on-demand packaging creation based on stored attribute data

专利摘要:
PACKAGE CREATION UNDER DEMAND BASED ON DATA FROM STORED ATTRIBUTES.The invention relates to methods, computer readable means, and systems described herein related to the production of packaging on demand. For example, packaging can be automatically produced on demand and scaled and configured for use with a customized set of items. In one respect, a request for multiple items is received and a packaging customization mechanism accesses an information repository that includes information about each item you request. The information can include scaled information about the three-dimensional size of the items. The packaging customization mechanism can use the dimensional information to simulate a model layout of all items ordered, and then calculate the dimensions of a box or other package that can provide a precise fit of the items when physically arranged according to the model layout. .
公开号:BR112013002654A2
申请号:R112013002654-5
申请日:2011-08-02
公开日:2020-10-06
发明作者:Niklas Pettersson；Ryan Osterhout
申请人:Packsize, Llc；
IPC主号:

专利说明:

"PACKAGE CREATION UNDER DEMAND BASED ON DATA FROM STORED ATTRIBUTES"
RELATED DEPOSIT REQUESTS This request claims Pat. Prov.
5 U.S. No. 61 / 370,402, filed on August 3, 2010, entitled "CREATING ON-DEMAND PACKAGING BASED ON STORED ATTRIBUTE DATA", such order is hereby incorporated by reference in its entirety for reference.
BACKGROUND OF THE INVENTION With the increasing availability of goods, products, and other items not only locally, but also through a global market, "the needs to properly package these materials for transportation and delivery have never been more important. Fortunately, The available Y 15 packaging can now be used to produce & virtually any packaging style. »Perhaps the most important factor in producing the packaging of a product is that the packaging is designed to fit the contained product as accurately as possible. a more precise fit, the item or product contained is not only less likely to be damaged, but the need for inner packaging is reduced and possibly eliminated, in particular when packaging materials such as corrugated cardboard are used to create a box or other packaging design, the materials are creased and folded as close as possible to a right angle. bending at right angles increase the strength characteristics of packaging materials
(essentially exponentially), thereby providing a resulting box with correspondingly increased resistance to damage when stacked.
A standard box has twenty-four right angles that make up its rectilinear shape. If one or more angles deviate from a right angle by more than a particular tolerance (for example, even just a few degrees), other angles can also be compromised and the strength of a resulting box reduced. When resistance decreases, the risk of die or loss to the confined item (s) increases. Also when the package fits loosely, similar streaks of damage or loss can occur as the sides of the package can bend, the corners can sag, and the right angles that make the package strong can be lost.
N The use of boxes or other packaging that provide a more accurate adjustment can thus provide a drastic reduction in loss and damage. A more precise adjustment also produces other significant savings, such as, for example, reducing the amount of material used to produce a box, reducing (and potentially eliminating) interior packaging, reducing shipping and handling fees, reducing time on the line. packaging, and / or increase transport performance.
25 The mechanism for building a box allows a manufacturer, producer and / or seller to adapt the desired dimensions of the resulting box. The mechanism then automatically generates a box model with appropriate cuts and folds. for items of higher volume (single items or item collections), carton sizes are generally pre-selected and prefabricated since repeated sales and / or storage of these items makes it economically possible to design a specific packaging for that item or collection of items.
However, it is generally not possible to pre-select box sizes and / or prefabricate boxes for low volume items, specialty items, exclusive item layouts, etc. For example, a supplier who operates an online store may receive an order for a wide variety of different items of different sizes, shapes, and configurations, this combination could be virtually impossible to predict in advance. These "15 combinations so far have made economic production difficult
P for customized packaging, due at least in part to
M time required for disposition and adaptation in a box size for each order that includes multiple items.
Consequently, this effort to design boxes 20 generally results in several standard size boxes instead of custom boxes. Thus, suppliers are often forced to choose a box from multiple standard size boxes, and then fill in the gaps inside the box with additional packaging materials.
25 BRIEF SUMMARY The modalities described here refer to a system for creating an on-demand package based on stored attribute data. The modalities described here include usable systems, machines, and usable computer media to efficiently and automatically produce customized packaging for a wide variety of different product and item combinations.
5 One modality includes creating customized packaging on demand. One or more items that will be included in a box or other packaging are identified.
For each or more items, dimensional information is accessed from an informational repository. The dimensional information 10 can include, for example, the size of the items in two or three dimensions. The items are arranged in a model arrangement based on the dimensional information accessed for one or more items. The dimensions of the model layout are calculated. From the dimensions of the layout P, {15 model, a customized packaging model for one or more items can be produced. The custom packaging model can be used to produce a custom flap (for example, a custom box) to contain items when items are arranged and positioned according to the model layout.
In some embodiments, item information can be accessed after receiving a request for one or more items, including a request that one or more items be packaged together. This request may be an order for these items, and may include more than one item.
In some cases, multiple items are a custom order. A packaging model can also be designed based on the calculated dimensions, or the calculated dimensions can be sent to a packaging production machine to design the packaging model and / or produce the packaging model based on the dimensions of the model layout.
5 Item placement in a model layout can be done in a wide variety of different ways. For example, the arrangement can be performed virtually, using one or more processors. For example, a virtual arrangement can be an electronic representation 10 of the items according to the stored dimensional information. The dimensional information can be graphical, or it can be used internally by the processor. The model layout can also be optimized. For example, the model layout can be optimized by evaluating the volume of 'J 15 one or more items, the volume of the model layout, the conservation area of the customized layout for the layout
Modeling, shipping, transportation or handling costs, the largest minimum item size, or other factors.
The arrangement of the items may also include producing multiple different model arrangements. The multiple arrangements can be produced iteratively, or using different algorithms. With multiple layouts, a particular model layout can be selected and the calculated dimensions are based on the selected model layout. To facilitate the production of multiple layouts, the information repository can include the dimensions of the items, whether the items can be nested with other items, and / or information about the cavities or nesting areas in which other items can be nested. The arrangement of the items to be packed can be carried out by a packaging customization mechanism that optionally operates in conjunction with a computer-readable storage medium that stores instructions on how to arrange the items and / or optimize the design of the model layout. An erdbalagern machine can also be operable to arrange and / or optimize the design, as well as produce a packaging model, for example, by cutting the model to match the calculated dimensions for the model layout.
Other embodiments of the invention include a system for creating and customizing packaging on demand. The system includes one or more storage media for a 'J 15 computer with an information repository that stores dimensional attributes for multiple different items. A packaging customization mechanism is configured to communicate with the information repository and receive a customized packaging request. The packaging customization mechanism is also configured to optimize an arrangement of the items to be packed to facilitate the design of the customized packaging.
The packaging customization mechanism is also configured to receive a packaging request for 25 customized packaging and to identify the items that will be packed. In response to a packaging request, the packaging customization mechanism is configured to access the information repository accessed and retrieve the dimensional attributes for the items to be packaged. The packaging customization mechanism is then configured to use those dimensional attributes to develop a standard layout of items to be packed. The 5 dimensions of a customized package can then be calculated, for example, when calculating the total volume or other dimensions of the model layout. The packaging customization mechanism or a packaging production machine can design the packaging model.
In additional infodalities, an on-demand box design and production system are configured for the automatic creation of customized boxes from any item collection. The system includes one or more processors and at least one computer-readable storage medium. At least one computer-readable storage medium contains a three-dimensional information repository of information about different items. A packaging customization mechanism that is executable by the processor to receive a request for multiple items to be boxed together. Each item can be found in the information repository, along with information about the three-dimensional size of each item. The information for each item can be aggregated and used to optimize a model layout of the items. The optimization of the items can include using the information of three-dimensional size to develop a virtual model that includes each item. The dimensions5 of the virtual model can then be calculated based on the three-dimensional size information for all items. Using the dimensions of the virtual model, the dimensions can be used to design a box model, or transmitted to a packaging production machine.
In each case, the dimensions can be used to draw a box model that houses the items when they are physically positioned in a way that corresponds to the virtual model.
By producing a packaging model (for example, a box), the packaging production machine can use the packaging model to produce a package that contains the multiple items. The packaging machine can use a paper-based product such as corrugated cardboard to store the packaging. Ern some modalities, continuous corrugated cardboard is used. The design can be optimized by automatically producing multiple layouts and then selecting one of the multiple layouts to satisfy the desired constraints.
This summary is provided to introduce a simplified selection of concepts that will be further described below in the Detailed Description. This summary is not intended to identify the fundamental characteristics or essential characteristics of the claimed subject, nor is it intended to be used as an aid to determine the scope of the claimed subject.
Additional features and advantages of the invention will be presented in the description that follows, and in part will be obvious from the description, or can be learned by practicing the invention. The characteristics and advantages of the invention can be realized and obtained by means of the instruments and combinations particularly pointed out in the appended claims. These and other features of the present invention will become more apparent from the following description and appended claims, or can be learned from the practice of the invention as shown below.
BRIEF DESCRIPTION OF THE DRAWINGS To better explain various aspects of the embodiments of the present invention, a more particular description of the invention will be provided by way of reference to specific embodiments of which are illustrated in the accompanying drawings. It is assessed that these drawings show only typical modalities of the invention and, therefore, are not considered to limit this scope, nor are the figures necessarily represented in scale. The invention will be described and explained with specificity and additional details using the attached drawings, in which: Figure 1 illustrates a system architecture that includes a packaging customization mechanism and a product information repository; Figure 2 illustrates a product dimension attribute information repository; Figure 3 illustrates a purchase order for a variety of products included within the product information repository in Figure 1; Figure 4 illustrates a flowchart of a method of producing a customized packaging for classifying items; Figures 5A-5C illustrate exemplary optimization procedures used in the production method of a custodized package of Figure 4; Figures 6A-6C illustrate exemplary product configurations identified in the optimization methods of Figures 5A-5C; and Figures 7A-7C illustrate exemplary case models and cases for the product configurations of Figures 6A-6C.
DETAILED DESCRIPTION The exemplary characteristics of the present invention refer to a system for creating packaging on demand. More particularly, the exemplary embodiments of the present invention relate to computer-readable systems, machines, and media usable for efficiently and automatically producing a customized packaging for a wide variety of different product and product combinations. Consequently, the exemplary fashions of the present invention can be used to efficiently produce packaging that is customized for unique combinations of items in a way that reduces the likelihood of damage or loss of the items, reduces q consumption of packaging materials and supplies, reduces costs handling, and / or reduce packaging time.
Now with reference to Figure 1, an exemplary embodiment of an on-demand packaging system 10 is illustrated, and includes a packaging customization mechanism 12 communicatively coupled to a product information repository 14. In the illustrated embodiment, the product information repository. product 14 includes a variety of types of information, including product dimension attributes 16 and product sales information
18. It should be evaluated in view of the description here, that although the product dimension attributes 16 and product sales information 18 are illustrated as separate collections of information, these can also be integrated into a single file, table, or other data collect.
Consequently, product information repository 14 is merely an example of a suitable information repository, and any suitable type of data repository can be used. For example, the product information repository 14 may include a relational database, a hierarchical database, a network database, an in-memory database, an object-oriented database, a data warehouse , any other suitable repository or database to hold the information, or a combination thereof. In fact, in some embodiments, the product information repository 14 may comprise a single physical database, while in other embodiments, the product information repository 14 may be distributed across multiple different physical locations.
In the illustrated embodiment, packaging customization mechanism 12 is additionally coupled to a packaging machine 20. Packaging machine 20 is an example of an on-demand packaging machine that can be used to produce packaging of different types and varieties according to with inputs provided manually and / or by the packaging customization mechanism 12. For example, as described in more detail here, the packaging machine 20 5 can receive input from the packaging customization mechanism 12 to produce a template for a packaging which is customized for one or more products.
As further illustrated in Figure 1, the packaging customization mechanism 12 is optionally coupled to an order processing mechanism 22. According to an exemplary embodiment, the on-demand packaging system 10 is used together with a supplier or manufacturer that supplies one or more different products. In an exemplary way, this supplier can receive an order for one or more products in the order processing mechanism 22. For example, a customer in a retail store can order a certain quantity of products, and a seller can enter the information for purchase directly from the order processing mechanism 22, or from one of the applications 24 which can then communicate the information with the order processing mechanism 22 (for example, using message 40). In another example, a customer can enter purchase information directly, such as using a web browser or other application 24 on a computing device that is connected via the network to the order processing mechanism 22.
Regardless of receiving order information, order processing mechanism 22 can receive a request that urine or more items have been ordered by a particular customer and will be stored and / or distributed to that customer. When the order processing mechanism 22 receives the request, the order processing mechanism 22 can also access the product information repository 14. For example, the order processing mechanism 22 can send a message 17 requesting access to information. of product sales 18, in response to this a response is provided that includes information on price, availability, shipping costs, and the like associated with these ordered products.
Optionally, the order processing mechanism 22 can also communicate information that it has received from the product information repository 14 with the customer. For example, the order processing mechanism can send the customer an order summary, purchase order, price information, delivery tracking information, and the like, anyone can include product sales information information 18. Information Product sales figures 18 can also be updated by the order processing mechanism 18 to add, delete, change, or otherwise edit a new or existing purchase order.
According to one embodiment, after the order processing mechanism 22 receives an order for one or more items, the order processing mechanism 22 communicates with c) packaging customization mechanism 12 to indicate that the packaging of the ordered items is needed. Such communication can occur at any time after the order processing mechanism 22 receives the order.
For example, order processing mechanism 22 may 5 send an order notice to the customization - packaging mechanism 12 at the time the order is received, or at any time that the ordered items are ready for delivery.
The information provided by the order processing mechanism 22 to the packaging customization mechanism 12 can take any form and, erroneously, takes the form of an electronic message 13 requesting that the customized packaging mechanism 12 produce a customized packaging - as a box - which will be used for storing and / or transporting the ordered items (for example, orders via message 40). When submitting a request 13, the order processing mechanism 22 can send information about the ordered products directly to the packaging customization mechanism 12, can send a reference to the product sales information 18, can send a usable order number by the packaging customization mechanism 12 to access the order in product sales information 18, or it can provide information in any way that allows the packaging customization mechanism 12 to identify the products that have been ordered.
In addition, according to some modalities it may not be necessary for the order processing mechanism 22 to provide any information about the order to the packaging customization mechanism 12. For example, a transport system (not shown) can connect to the packaging mechanism order processing 22. At the time of transport, it is desired that the transport system be able to send a customized packaging request to the packaging customization mechanism 12, so that no direct communication from the order processing mechanism 22 with the packaging mechanism packaging customization 12 is required. It should also be appreciated that although the order processing mechanism 22, packaging customization mechanism 12, and the transport system are shown and / or described separately, one or more can also be integrated into a single system or mechanism. For example, the order processing mechanism 22 may also include the packaging customization mechanism 12 as a part of this.
Still with reference to Figure 1, when the packaging custody mechanism 12 receives a request for customized packaging 13, or some other information that identifies the products ordered, the packaging customization mechanism 12 can access the product dimension attributes 16 and / or obtain additional information about the products ordered. For example, the ernbalagern customization mechanism 12 can send a query message 15 to the product information repository 14 to request dimensional information about the ordered products. For example, and as discussed in more detail with reference to Figure 2, the product dimension attributes 16 that are provided in response to query message 15 may include information about the dimensions of each item that is a part of the same order. These dimensions can include height, width, length, radius of curvature, and other information that can be used by the packaging customization mechanism 12 to develop an arrangement of the ordered products so that the total dimensions of a customized packaging design can be calculated.
Once the packaging customization mechanism 12 accesses the dimensional attributes of the products and develops a layout, the packaging customization mechanism 12 can also design a packaging model. In particular, the packaging customization mechanism 12 can use the height, length, width, and / or other layout information created to identify the volume of a box or other packaging required to confine the layout of items as calculated by the customization mechanism. of packaging 12, and then draw a model corresponding to that volume. This design can, however, be performed by the packaging machine 20. For example, the packaging customization mechanism 12 can develop an arrangement of ordered items, and then provide the desired packaging or packaging directions to the packaging machine 20 (for example, when sending a message 19), to allow the packaging machine 20 to design the packaging pattern.
The packaging machine 20 can also access packaging materials 26 of one or more types and / or sizes.
For example, according to one embodiment, the packaging machine 20 is fed by continuous corrugated cardboard of one or more sizes. Based on the packaging dimensions required for a particular order, the packaging machine 20 can then selectively feed itself sufficiently. from the continuous corrugated cardboard to quote the continuous material in a desired box model, as well as making any necessary cuts, folds, perforations, cut lines, and the like. The box model can then be assembled randomly, or automatically, and the ordered products can be inserted into it.
Erribora the packaging system on demand 10 is mainly discussed with reference to the fulfillment of a customer order, it should be evaluated in view of the description here that this is merely exemplary, and that in other modalities, the packaging customization mechanism 12 can operate without any order being placed.
For example, the packaging customization mechanism 12 can receive information about a variety of objects that the owner or operator of the system 10 wants to store, pack, or transport, regardless of any particular order. In fact, system 10 can be used to produce a customized packaging of any kind since it is known that the items will be packed, regardless of the reason why this packaging was requested.
Now with reference to Figure 2, there is an exemplary repository of dimensional attributes of product 16. In particular, Figure 2 illustrates a table 30
'in which various types of information, about items or products. different can be stored. In the example in Figure 2, table 30 includes an item column 32 that identifies each product from which dimensional attribute information 5 was collected. The information in item column 32 may in turn include some type of identification for each product. In the illustrated example, AA-RR products are shown; however, vertical ellipses are provided to indicate that additional products can also be included. In addition, the type of information used to identify a product may vary. This information can include, for example, a product name, product number, model number, SKU number, or any other unique identifier for an item. For each item, + 15 different types of information that can then be included can be used by the customization mechanism. packaging to arrange virtually different items so that a packaging model can be produced. A layout can be virtual, for example, by producing a simulated model of the items that will be contained in a particular layout, so that when the items are physically collected, they can be physically arranged that corresponds to the simulated model.
Among other information, table 30 can include 25 dimensional information about the volume of the items that will be included in the packaging. For example, columns with the headings Dx, Dy, and Dz can be used to denote the length, width, and height of the items. By using this information, the packaging customization mechanism can then create a virtual layout of all products in an order to determine the total dimensions of the information.
5 Other dimensional information besides mere information on straight length, width, and height can also be used. For example, in some embodiments, information about curves, irregularities, and / or other dimensions of the various items can be stored so that they can be considered so that the packaging custody mechanism 12 produces an optimal arrangement of items. In another way, table 30 can store, or make reference to, three-dimensional models of the items to be packed. As a result, the packaging customization mechanism 12 can then access the product templates and provide a virtual set using the templates themselves to optimize item placement as discussed here.
According to a modality, additional dimensional information includes whether the item is stackable or not. For example, the volume information about the length, width and height of an item cannot be transmitted if other items can also fit within the same volume as the nesting item. For example, a tubular container is considered. The basic information for length, width and height does not include any information that the item is hollow, or the size of the hollow tube. When indicating that an item is nestable, however, table 30 can be used to arrange items more efficiently so that items can be nested within each other. However, nesting items is not limited to hollow objects or objects with holes. For example, an irregularly shaped item 5 may have an external cavity within which one or more items can be adjusted within the volume identified for the irregularly shaped item.
To make it easier to nest items, additional information about the available cavity can be included.
The illustrated modality includes, for example, cavity length, width, and height information (ie, Cx, Cy, and Cz in table 30). By identifying the size of an nestable cavity or area of an item, the packaging customization mechanism 12 can further optimize the disposition of items to then reduce costs at least in packaging materials and handling costs associated with the total enibalagern of multiple items .
In some embodiments, the weight of the tarnbérn items can be provided in the attribute table 30. Weight information can be used, for example, to provide information to the packaging customization mechanism 12 that can be used to separate the items. For example, as discussed in more detail here, weight information can be used to optimize handling or transportation costs. Transport costs can increase dramatically as the total weight of a package increases, to optimize handling or transportation costs, the packaging customization mechanism 12 can determine that the ordered items must be separated into two or more separate containers, and then calculate the dimensions of each separate package.
5 In yet other modalities, table 30 may include guidance information about a particular item.
For example, if a particular item is to be oriented so that a particular direction is facing up, that direction can be specified in table 30. In particular, table 30 shows two items that have specific orientations. The HH product, for example, is indicated to require that the "z" direction be oriented in a particular way, and information about the NN product indicates that the "x" direction must be oriented in a specific way.
Additional information may further indicate that guidance is requested or required, or the guidance information in table 30 can be understood to have a particular meaning (for example, the z direction of product HH must be vertically oriented and / or the x direction of NN product must be vertically oriented). The guidance information is, however, optional and may or may not be used to arrange the items in the customized packaging.
It should be noted that Figure 2 is merely an example of an adequate repository of information for dimensional product attributes, and that Table 30 may include a variety of other types of information. In fact, as illustrated in Figure 2, the horizontal ellipses indicate that numerous other attributes can also be stored in table 30. These attributes can refer to dimensional information or other attributes of associated items. For example, additional information may include information about curvatures or irregularities in a product, if the product has multiple cavities in which other products can be nested, if a cavity is an opening, hollow center, irregularity, etc., as well as other information such as price information, stock position, or order information. Additional information can indicate, for example, whether a product is flexible. A flexible product may be able to be placed in different configurations. For example, a shirt can be flexible and fit a variety of different sizes and locations within a package. In addition, if an item is flexible, fragile, or has other characteristics, the table may include information that indicates that this item should not be used as the basis for heavier items.
Now with reference to Figure 3, an exemplary purchase order 40 is illustrated where an ABC, LLC customer of an XYZ Corp. seller. placed an order for several products identified within table 30 of E'igura 2. In Figure 3, it can be seen that twenty-six items were ordered, and that the twenty-six items include twelve different types of items. The purchase order 40 of Figure 3 is merely an example of any purchase order or other request that certain items are packed together; however, the particular example in Figure 3 will be used in more detail with respect to Figures 6A-6C to show lines in which items 42 in purchase order 40 can be arranged in accordance with the modalities of the present invention.
5 Now with reference to Figure 4, an exemplary method of producing customized packaging 50 is provided. As shown, method 50 can include several actions and steps (some optionally) performed by different components of a customized packaging system on demand. The actions and steps of method 50 will be described in relation to the packaging customization mechanism 12 and packaging machine 20 of Figure 1, although these actions and steps may be alternatively or additionally performed by other components or systems.
As shown, method 50 includes an action from a packaging customization mechanism that receives a request (action 52). For example, the packaging customization mechanism 12 can receive a request 13 from the order processing mechanism 22. The request received for, for example, requesting the packaging custody mechanism 12 to prepare the customized packaging for an order, delivery, or another collection of one or more items (for example, purchase order 40 made with the order processing mechanism 22 via other applications 24). The request can identify these ordered items, or it can provide information that the packaging customization mechanism 12 can then use to identify the items for which the customized packaging is desired.
Method 50 also includes an action of the packaging custody mechanism that identifies the i.tens (action 54).
For example, as a result, and in response to the receipt of 5 request 13 from the order processing mechanism 22, the packaging customization mechanism 12 can identify one or more items in the purchase order 40 for which the customized packaging is being requested. .
Method 50 includes a step to optimize packaging (step 56). Step 56 can include any corresponding action to implement the packaging optimization result. Step 56 may include packaging optimization for a variety of different products (for example, multiple products ordered in purchase order 40). In addition, step 56 can be used to optimize packaging when no standard packaging or box is available or, as described below, you can optimize packaging by selecting a particular standard packaging or box for the items identified.
In one embodiment, step 56 includes an action to determine whether the collection of one or more items in the order consists of all or part of a common package (action 58).
For example, after items are identified, the packaging custody mechanism 12 can access product information 14 and identify common orders. In addition, or alternatively, information about regular orders can be stored in the packaging customization mechanism 12, in the order processing mechanism 14, or in other suitable locations.
An order can be considered a common order when 'an order is for a single item and the seller often sells that single item separately.
5 Alternatively, an order for multiple different items, multiple quantities of the same item, or a combination of these, can be commonly processed by the seller, and thus also considered a common order. The frequency of a particular set of items in orders, or the number of orders that must be processed before an order can be considered with a common order is configurable, and will likely depend on the vendor, industry, particular products, and the like. If in action 58 an order is determined as a common order for which a standard box has been designed and / or supplied, the dimensions of a standard package for the common order can be obtained (action 60). For example, the packaging customization mechanism 12 can access an internal repository, and can access information repository 14 or some other suitable location, and obtain the dimensions of the packaging normally used for the common order.
If the determination in action 58 results in a determination that the items identified in action 54 do not.
part of a common order for which a standard box was provided, method 50 can proceed to determine whether a previous order was made for the same item collection (action 62). For example, the packaging customization mechanism 12 can search for previous orders including an identical set of items. In one example, the packaging customization mechanism 12 sends a query15 to the product information repository 15 that searches for previous orders from the same person or entity that requested 5 the items identified in action 54. Other searches may be additionally or alternatively performed to previous orders or packaging requests. For example, query 15 may request that the product information repository 14 identify any order for identical items, or identically sized items, regardless of the entity requesting the items. If an identical previous order is found, a search for the dimensions of a customized packaging for such an identical previous order can be performed (action 64). For example, the packaging customization mechanism 12 can retrieve information through query 15 of information repository 14 that identifies an identical previous order.
Upon returning a response to query 15, the information repository 14 can also provide the packaging customization agent 12 with the dimensions of the packaging used for the previous order. In addition, or alternatively, the response can also identify for the packaging customization mechanism 12 a model arrangement of these items within the packaging of the identified dimensions.
The determination that a previous order was made for identical items (action 62) can also include, in some ways, determining whether the order is identical to an aggregate of two or more previous orders for which the customized packaging was created. For example, the packaging customization mechanism 12 can send a query 15 to the information repository 14 (or alternatively to the order processing mechanism 5 22) that identifies the items ordered. If, for example, twelve or twenty-six items of purchase order 40 in Figure 3 were previously ordered in one order, and the remaining fourteen were ordered in a second separate order, the information repository 14 or the order processing mechanism 22 can send a return response to the packaging customization mechanism 12 that identifies these previous orders, and optionally also provides the dimensions of the two previously customized packaging and / or the model arrangements of these items for use with the customized packaging.
When the items identified in action 54 are not identical to any previous request, or optionally the aggregate of previous orders, it can be assumed that a new customized packaging is desired. A determination to create a new custoniized packaging can be a standard parameter when a negative response is received for the determination in action 62, however, in other cases an administrator or user of system 10 may specifically request the customized packaging. In any case, when a new customized packaging is desired or necessary, the dimensional attributes of the items to be packed can be accessed (action 66). For example, the packaging customization mechanism 12 can send the query 15 to the product information repository 14 for dimensional attributes of the items in the purchase order.
40. Information about these items can be stored in product dimension attributes 16 and can then be returned 5 from the product information repository 14 to the packaging customization mechanism 12. The specific dimensional attributes that are accessed can be varied and they may include, for example, information about the size, shape, weight, orientation, and the like of each individual item that will be packaged.
Once the information on the dimensions of each item was obtained in action 66, the items that will be unbalanced can be arranged to carry out the packaging in the customized packaging (action 68). Action 68 may include, for example, the packaging customization mechanism 12 that performs a simulation that provides virtually the items that will be packaged based on the dimensional attributes retrieved in action 66. This arrangement can be purely virtual and does not require items 're reais are arranged, err in other ways, the packaging customization mechanism 12 can access the items to be packaged, or models thereof, and use robotics or manual capabilities to physically dispose of the ~ items to be packaged. According to an example, the packaging customization mechanism 12 can receive three-dimensional models of each item that will be packaged from the product information repository 14 in response to query 15, and can use these three-dimensional models to perform a virtual layout of the items. Some exemplary methods for arranging items for customized packaging (action 68) are described in more detail in relation to Figures 5A-5C.
5 After an appropriate disposition of items is produced in action 68, method 50 can proceed to determine the dimensions of the customized packaging (action 70).
According to an example, the packaging customization mechanism 12 uses the dimensional attributes obtained in action 66 and the model layout produced in action 68 to calculate the total dimensions of the model layout, and then also determines the dimensions required for the required custom packaging. to contain the items to be packed. The desired carton pack may optionally have a generally rectangular configuration, and the arrangement of items in action 68 can then be optionally optimized for that rectangular configuration.
Consequently, the determination of the customized packaging dimensions (action 70) may include the packaging customization mechanism 12 that calculates, measures, computes, or otherwise identifies the length, width, and height of the inside of a customized packaging suitable for contain the disposition of items to be packed.
Once the dimensions of the customized packaging have been identified, either by creating a new customized packaging on demand, or by searching for a previously used or standard size packaging model, the determined dimensions can then be sent to a packaging machine. packaging for the production of the customized enibalagem (action 72), and the determined dimensions can be received by the packaging machine (action 74). For example, the packaging customization mechanism 12 can calculate the maximum height, length, and width of the standard layout of the items, and send those dimensions to the packaging production machine 20. Although the dimensions of the model layout can be sent in one example, in another example, the dimensions that are sent in action 72 may correspond to the dimensions of the customized packaging.
Upon receipt of the dimensions of the model layout, the packaging model can be designed (action 76).
For example, a packaging production machine 20 can receive a message 19 from the customizing mechanism of the flapper 12, and a message 19 can provide the dimensions of a customized and / or optimized item layout. Upon receipt of this message 19, the packaging production machine 20 can then automatically design a suitable box model to provide the desired dimensions. This box model can generally correspond to the dimensions received in message 19, but it can optionally increase the size of the custom packaging. Estimate the size deviations of the items that will be ordered, to allow the internal packaging materials to be inserted, to estimate the differences in internal dimensions vs. customized packaging, or for other reasons.
Consequently, in a fashion, the packaging production machine 20 can receive the dimensions of flapping in action 74, and it can then design the packaging model in action 76. The design of the packaging model in action 76, is carried out by packaging machine 20, packaging customization mechanism 12, or some other entity, may include searching for a previously used model, or performing a new calculation for a model. For a new model, the new model can be automatically designed by the packaging machine 20, so that the amount of corrugated cardboard or other necessary material is automatically determined, together with the desired locations for cuts, folds, cut lines, perforations, and other features that can facilitate the assembly of the packaging, packaging of the model in a complete package suitable for receiving and maintaining the items identified in action 54. Based on the model, the packaging model can be cut to provide a customized packaging specific to the identified items (action 78). For example, the packaging machine 20 can be fed with packaging materials 26 and cut a model of the size and shape determined in action 76.
Although method 50 is described in relation to the packaging machine 20 that designs the packaging model (action 76), an element versed in the technique will evaluate in view of the description here that this action can alternatively be performed by other architectural components. For example, the packaging customization mechanism 12 can optionally compute the dimensions of the model layout and also design the packaging model that will be used to contain this arrangement. So, instead of supplying the packaging dimensions to the packaging machine 20 in action 72, the packaging customization mechanism 12 can supply the packaging machine 20 with the model drawing.
The design of the packaging model, whether performed by the packaging machine 20, the packaging customization mechanism 12, or some other entity, may include researching a previously used model, or performing a new calculation for a model. For a new model, the new model can be automatically designed by the packaging machine 20, so that the amount of corrugated paper or other necessary material is automatically determined, along with the desired locations for cuts, 15 folds, cut lines, perforations, and other resources that can facilitate the assembly of the model packaging in a complete package suitable for receiving and maintaining the items identified in the virtual / simulated model layout.
Any suitable way to automatically draw the model can be used. According to one embodiment, the packaging machine 20 may have access to the packaging materials in the form of continuous corrugated cardboard. This continuous corrugated board can be accessible in a single size, or in multiple sizes. Since this design is being produced (for example, by the packaging machine 20 or the packaging customization mechanism 12), the design itself can be optimized based on the available materials, to reduce the use of corrugated board certain widths of continuous material are available. Thus, the system can determine the best way for Eazer to have the box reduce the amount of corrugated cardboard or other packaging materials that are used.
Other requirements or factors can also be considered. For example, a package may have a minimum size restriction. This can occur for a number of reasons, including a restriction due to the need to place a shipping label on a packaging panel.
In addition, automatic tape sealers and glue devices may have size restrictions that are considered to optimize packaging size and design.
For example, a tape sealer can operate only with 15 packs of certain aspect ratios without obstruction. It will be assessed in view of the description here that the method 50 provided can thus provide an automatic method by which an order or requests for specific items can be received, and from which a box model or any specific packaging model for those orders can be automatically designed and produced without the need for human intervention. In fact, method 50 can not only provide an automatic mechanism for producing customized packaging, but 25 can also automatically determine an optimal or almost optimal way to position items in the customized packaging. Then, the customized packaging can be assembled and then automatically or manually loaded with the items to be packaged identified. In the case of manually loading the customized packaging, the packaging mechanism for custom packaging 12 or packaging machine 20 can optionally produce instructions, drawings, diagrams, or 5 other indications to help the person in the packaging line to load the items in the packaging customized in the same way designed based on the model layout.
In still other modalities, however, some human or manual intervention may be desired before a packaging model is designed and cut. For example, in one mode, different layout models are available for the items to be packaged, and each possibility may have different advantages. In some modalities, an operator of system 10 can therefore provide some input so that this option is selected for customized packaging. For example, the packaging customization mechanism 12 can identify multiple possible layouts and graphically, audibly, or otherwise provide information that an operator can use to view information about the different layouts, or the packaging designs for each disposition.
For example, the packaging customization mechanism 12 can identify a model layout that provides a packaging model that minimizes the volume of customized packaging, while another model layout minimizes shipping / transportation costs, and yet another layout can minimize the amount of packaging. corrugated cardboard or other packaging material 26 used to produce the model. While a determination whose model is desired can be made automatically, an alternative may include providing a user with details about each provision, including possibly the advantages and disadvantages of each.
5 For example, the packaging customization mechanism 12 can advise an operator to select a desired design from multiple possible options.
Alternatively, instead of warning the user about a desired design for a particular selection of items, the
10. selection> can be performed automatically based on predefined c-settings or preferences. For example, an ad-ministrator or operator may specify that the model's reduced area, reduced volume, reduced transport costs, reduced width dimensions, certain weight conditions, or other attributes must have higher priority, and then a design can be automatically selected based on the default setting. For example, the packaging machine 20 or enibalizing customization mechanism 12 can automatically select a design based on these predetermined settings or preferences.
Now with reference to Figure 5A-5C, various exemplary modalities of methods for arranging items for customized packaging are described. It will be appreciated that methods 68a-68c are provided merely as examples of suitable methods to customize and optimize the packaging according to various parameters, but that other parameters and optimization strategies are contemplated within the scope of the present invention. Consequently, no assumption should be made that any element of methods 68a-68c is required or essential except where explicitly claimed.
5 Figure 5A, for example, provides a volumetric optimization disposition method 68a that can be used to arrange items for action 68 of method 50 in Figure 4. In method 68a, particular attention is paid to the volume of the customized packaging for confine a particular arrangement of items to be packaged. In particular, method 68a begins (action 80) and the cumulative volume of all items is computed (action 82). With reference to the architecture in Figure 1, the computation of the volume of items in action 82 can be performed by the packaging customization mechanism 12, and may include calculating the volume of all the items that will be individually packaged, and then adding all these voIumes. When an included item can allow other items to be nested, action 82 optionally includes excluding the volume of the nesting item's cavity from the combined volume calculation.
Before, after, or simultaneously with the calculation of the cumulative combined volume of all items in action 82, a possible model arrangement of the items can be produced (action 84). This arrangement can be produced by the packaging customization mechanism 12 in an example, and can be virtual since the packaging customization mechanism 12 does not have to physically arrange the items, although in other modalities, the packaging customization mechanism 12 you can physically arrange the items to be packed. Regardless of whether the arrangement is performed virtually or physically, the length, width, and height directions for an enibalation to be able to confine the particular arrangement can be identified, this also allows a package volume to be calculated (action 86).
Then, the volume of the package as determined in action 86 can be compared with the corrected volume of the items as determined in action 82. For example, a determination can be made to verify that the volume of packaging exceeds the volume combined with an amount limit (action 88).
In one embodiment, action 88 is determined by the packaging customization mechanism 12.
This determination can be based on any suitable limit (for example, 5%). Then, based on the volume compared to the customized packaging with the cumulative volume of the individual items, the items that will be packed can be rearranged (action 90) or the method can end (action 92).
For example, in a mode where the limit is set to 5%, the packaging customization mechanism 12 can determine whether the packaging volume exceeds the combined item volume by more than 5%. If the packaging volume exceeds this limit, the packaging custody mechanism 12 may also determine that a new model arrangement is desired for better or more efficient results, and the same items can be rearranged to have a new model arrangement in action 90. If the packaging volume is less than the 5% limit, the packaging customization mechanism 12 can determine that the model arrangement is suitably optimal, and method 68a can end 92. So, a packaging model suitable for the Model layout can be designed and / or produced. Method 68a thus provides, in one embodiment, an iterative approach to arranging the items to be packaged. In particular, method 68a can allow multiple arrangements to be calculated and compared to a desired parameter (for example, the volume of items vs.
volume of the model layout) and when an adequate volume is obtained, the method can be used.
The 5% limit as provided in the example above is purely explanatory, and the particular limit that is used, if any, may be configurable by an administrator or operator, may vary based on the volume of the package, or vary based on numerous other criteria.
For example, the limit can be less than 5% (for example, between about 2% and 5%) or greater than 5 ° 5 (between 5 ° 5 and about 20%). In other modalities, the limit varies directly with the volume, so that the greater the combined volume of all items, the greater the limit value.
Although method 68a organizes and rearranges the items that will be packaged based on a volume and terrnine calculation as soon as a suitable volume below the threshold is found, this is also just an example. In some embodiments, for example, it may be impossible to produce an arrangement that results in a volume of packaging falling below a particular limit level.
In such cases, method 68a optionally includes using a counter, and whenever a new disposition of items is produced in action 90, the counter can be increased (action 94). For example, the packaging customization mechanism 512 may include an internal counter that increases with each disposition and / or re-disposition of the items to be packed. Optionally, method 68 also evaluates the number of provisions produced after each volume comparison is made in action 88. For example, after a packaging volume has been determined to exceed the limit, q counter can be evaluated to determine if the counter has reached a max counter value (action 96). If the maximum counter value is not reached, method 68a can proceed again to reorganize the items in action 90. If, however, action determination 96 determines that the maximum counter value has been reached, method 68a can proceed and a analysis of the necessary packaging volume for each item disposition in actions 84 and 90 can be performed, with a selection of the disposition that has the lowest volume (action 98). For example, the packaging customization mechanism 12 can store at least temporarily information about each model arrangement produced and, in action 98, it can compare the volume information of each model arrangement to determine that the model arrangement has the lowest volume. The lowest volume layout can then be selected and the dimensions used to design and cut a suitable packaging model.
In addition, it should be assessed in view of the description here that it is also not necessary to compare the packaging volume with a combined volume of all items, and that method 68a is just an example. In fact, multiple dispositions of the items to be packed can be produced, and the disposition with the lowest volume can be selected (without the need to compare the volumes with the aggregated volume of the items to be e-packaged). The number of provisions and re-dispositions that is produced and compared can be adjusted to a predetermined number (for example, by incrementing the counter), can be limited based on time (for example, computing the maximum possible dispositions produced in one minute ), or can be I'mitmitted or configured in other ways.
Now referring to Figure 5B, another example of a method for arranging items in a customized package is described (method 68b). In particular, Figure 5B illustrates an exemplary method 68b that particularly identifies the cost of customized packaging in terms of transportation, shipping, and / or other handling costs, and produces a provision that minimizes those costs.
Specifically, method 68b begins (action 100) and the weight of all items to be packed is calculated (action 102). For example, the enibalagern customization mechanism 12 can send a query 15 to access the product dimension attributes 16 in the product information repository 14, and receive a request that includes information about the unpacked weight of these items.
The costs associated with the transportation of an item can also be accessed and / or (for example, through the · packaging customization mechanism 12 that accesses a repository of terms and transportation costs in the information repository 5 of product 14 or through other applications 24). The costs of transportation, handling, and / or shipping associated with the items to be corrected may depend, at least in part, on the combined weight of the items to be packed. To determine whether the weight can be optimized for transport costs, the total weight can be divided into two or more errtbalances (action 106). The total weight can be divided into action 106, for example, using product weight information in product sales information 18 and / or product dimension attributes 16 from 15 information repository 14, and separating specific items to produce the desired weights For example, the U customization mechanism.
of packaging 12 can obtain information about the weights of the items that will be packed through consultation 15 and then divide uniformly between two or more packages.
20 Alternatively, the packaging customization mechanism 12 can designate weights in other proportions (for example, selecting a weight based on a maximum weight-cost ratio).
Based on the particular combination of items, each 25 can produce different weights for a particular package, the cost of transport for the single package can be compared with c) the combined cost of transporting multiple low weight packages (action 108). If the single package is more expensive than the multiple packages, method 68b proceeds to arrange the items in a single package (action 110). However, if the arrangement of the items in multiple packages can reduce the costs of transportation as determined in action 108, the items can then be arranged in multiple packages (action 112). After disposing of the items in a single package (action 110) or multiple packages (action 108), method 68b can end (action 114). After a particular model arrangement of one or more separate packages has been produced and method 68b is finished, information about that model arrangement can be used to produce one or more packaging models to contain those arrangements.
According to method 68a of Figure 5A, method 68b in Figure 5B is also able to be performed iteratively. For example, in action 106, the total weight of the items to be packed can be divided into several different proportions, and the shipping costs associated with each combination can be calculated. Then, in action 108, a determination can be made for which combination provide lower transportation costs, and a disposal or re-disposal can then be done by separating the items in a way that provides the desired weights.
In addition, it will be easily assessed that transportation, handling, and shipping costs may be influenced by factors other than weight. For example, the dimensions of a customized packaging can also influence the cost of transportation, handling, shipping or other costs.
Consequently, method 68b can be easily adapted by an element skilled in the art in view of the description here to include additional considerations. For example, an iterative process can be implemented to not only separate 5 items in different weights, but also to make an arrangement before action 108 that determines the transport costs associated with a single package and multiple packages. Thus, method 68b can be optimized to provide reduced shipping based on weight, physical dimensions, and / or other factors.
Now with reference to Figure 5C, another exemplary modality is described to arrange the items of the customized packaging. In particular, method 68c in Figure 5C specifically sets out items based on a larger minimum dimension, although other considerations can also be assessed.
The 68C method starts (action 120) and the dimensional attributes for one or more items to be packaged can be accessed (action 122). For example, the packaging customization engine 12 can query product information repository 15 and obtain dimensional information from one or more files that describe product dimension attributes 16. Regardless of how to access dimensional attributes, a greater minimum dimension can be determined (action 124). For example, with reference to table 30 in Figure 2, the packaging customization mechanism 12 can receive information from the product information repository 14 that identifies c)
item GG as having the largest minimum dimension. For example, the packaging customization mechanism 12 can iterate through table 30 and determine that the smallest dimension of item GG is twenty, and each item listed in table 30 5 has at least one smaller dimension. In another example, the items in purchase order 40 in Figure 3 can be identified and the packaging customization mechanism 12 can obtain product dimension attributes 12 for each item. In this example, the item GG may not be ordered, and the packaging customization mechanism 12 may determine that KK has a minimum dimension of ten, which is greater than the minimum order of any other item ordered using the purchase order 40.
The largest minimum size can represent the smallest possible size for a customized packaging that confines all items that will be packaged in a single package.
In one embodiment, the disposal method 68c can then use the largest minimum dimension as determined in action 124 since it disposes of the items that will be packaged using the largest minimum dimension as a base dimension (action 126). For example, the packaging customization mechanism 12 can simulate an arrangement of the items to be packed by adjusting the largest minimum length as a total width of the customized packaging, and set the width difference so that the width of the simulated model layout does not exceed the largest minimum dimension. Then, the items can be placed on, around, or inside the object that has the largest minimum dimension, provided that in that direction
(for example, the Width) is not increased. For example, the packaging customization mechanism 12 can position the item with the largest minimum dimension and then position other items in relation to that item. When all objects are placed in this manner, method 68c may terminate (action 128).
It should be easily assessed in view of the description here that method 68c can also be adapted and modified in a number of ways. For example, the 68C method can be an iterative process. Multiple layouts are made, and one of the layouts is finally selected based on some criteria (for example, handling costs, volume, area, weight, etc.). Furthermore, the largest minimum dimension can in itself provide a starting point for a base dimension. As an example, various tolerances can be applied to increase the minimum minimum enough to allow items to be easily and efficiently placed inside the customized packaging.
In addition, or alternatively, some other algorithm or calculation can be performed to select and arrange the items in relation to the item (s) identified as having the largest minimum dimension. In addition, multiple minimum minimum dimensions can be calculated. For example, if the items to be packed are separated into multiple packages, each of the multiple packages may have a greater minimum dimension associated with it.
The specific way of disposing and optionally disposing of the items to be packaged (for example, in methods 50 and 68a-68c) can thus be varied and carried out in a number of ways. In one mode, for example, an item can be selected randomly, or pseudo-randomly. Then another item can be selected and placed in, around, or within the last item selected, and this process can continue for each item. The progressive selection of items can also be random or pseudo-random, although in other modalities the items are selected based at least in part on their dimensions so that the items can collectively form an arrangement that has a generally rectilinear shape. Item selection can also be an iterative process in itself, and an item can be moved over and over before an arrangement or re-arrangement of all items is completed.
In some cases, the actual arrangement of items may occur by combining the particular dimensions of multiple items (for example, width with width, length with length, etc.) in a generally two-dimensional manner, so that the items are generally arranged side by side or from end to end. The methods described here are, however, not so limited. For example, the packaging customization mechanism 12 can receive three-dimensional attribute information from the product information repository 14, and can then manipulate the items to be packaged in three dimensions vertically or physically. For example, the packaging customization mechanism 12 can rotate items relative to each other, space items vertically or horizontally, place items close to, inside, or stacked on top of each other, or otherwise arranged to produce one three-dimensional arrangement. Additionally, since the customized packaging can be created to be generally straight in shape, the disposition of the items can take into account other aspects such as, for example, the disposition of items close to the corners and / or edges to reinforce and protect these edges or corners against damage, then acting to preserve the integrity of the customized packaging.
Although various disposal strategies are described here, illustrative methods (for example, methods 50 and 68a-68c) may not be combined and / or replaced with other disposal methods. For example, in one embodiment, a method for arranging items can produce different layouts using an iterative process, and then can evaluate all calculated layouts based on the minimum amount of corrugated cardboard or other necessary packaging material. This consideration may be of particular interest to certain entities that do not provide a capital investment for a packaging machine, but pay to use such a machine based on the area of the corrugated board used.
In still other modalities, the area, volume, shipping / transportation, and other considerations are collectively considered (for example, with different weight values) to automatically determine the arrangement that should be used to produce the customized packaging.
Now with reference to Figures 6A-6C, several exemplary embodiments of arrangements that can be produced in accordance with the present invention are illustrated.
In particular, Figures 6A-6C are illustrative of several exemplary item arrangements corresponding to purchase order 40 in Figure 3, and with the dimensions in Table 30 in Figure 2.
Figure 6A, for example, illustrates a model 130 layout of the items, and quantities of those items, identified in the purchase order 40. A total of twenty-six items are included in the model 130 layout, and it can be seen that the layout particular has a generally straight configuration. In one embodiment, the illustrated layout 130 is produced by arranging items according to method 68a which optimizes layout 130 based on the volume of layout 130 as compared to the total volume of items to be erbalized, the volume of other arrangements considered , or both.
As shown in Figure 6A, the arrangement 130 is generally rectilinear and has dimensions of length (x), width (y), and height (Z). based on the directional attributes in table 30 of Figure 2, layout 130 can have approximately the dimensions identified below in Table 1.
Figure 6B illustrates another exemplary arrangement of the twenty-six items ordered using purchase order 40 in Figure 3. In that arrangement, the items that will be packaged were separated into two separate layout arrangements 140a, 140b. According to an example, model arrangements 140a, 140b were selected using a packaging customization mechanism 12 that realizes method 68b. For example, the 5 packaging customization mechanism 12 can select the items that will be included in each layout model 140a, 140b and also perform the virtual layout of these, based on a restriction that wants to reduce the costs associated with the transport and handling of an urn collecting items.
Figure 6C illustrates yet another example arrangement 150 of the items ordered using purchase order 40 in Figure 3. As will be assessed when comparing arrangement 150 with provisions 130, 140a, and 140b, arrangement 150 may include the common item arrangement. , but have dimensions that are significantly different from those of other provisions that can be produced or considered. For example, using one or more disposition methods, the packaging customization mechanism 12 can produce each disposition 130, 140a, 140b and 150, and each - can have significantly different total dimensional attributes, despite the consistent dimensional attributes of the individual items that will be packed. According to one embodiment, the model arrangement 150 can be produced using method 68a or method 68b, although in another embodiment, arrangement 150 is produced by considering the highest minimum flow according to method 68c of Figure 5C.
Figures 7A-7C illustrate various packaging models 160, 170a, 170b, and 170C that can be produced by packaging machine 20 as customized templates for the particular set of items identified in purchase order 40. Figure 7A, for example, illustrates a package 5 model 160 produced by the packaging production machine 20, as well as an assembled configuration thereof. As produced, the model 160 can be produced from corrugated cardboard or other packaging materials and have wrinkles and / or cuts automatically created to facilitate the folding and assembly of packaging 160 by the packaging machine.
20. To illustrate a way to fold a model 160 in an assembled configuration, Figure 7A illustrates each panel A-L in a model and the corresponding locations of these panels as visible in the assembled and folded configuration.
The model 160 can be produced by the packaging machine 20 and can be designed to have approximately the same dimensions as a particular arrangement of items for which the model has been provided (for example, items ordered in purchase order 40). The packaging model 160, for example, includes dimensions of length (X), width (y), and height (z) which generally correspond to the same dimensions of the arrangement 130 illustrated in Figure 6 A. Similarly, the models 170a and 170b have dimensions of length (x), width (y), and height (z) which generally correspond to the same dimensions of dispositions 140a, 140b, respectively, illustrated in Figure 6B. Figure 7C illustrates a customized packaging model 180 generally corresponding to the specific arrangement 180 of items illustrated in Figure 6C. Table 1 provides several exemplary details regarding the directional aspects of provisions 130, 140a, 140b, and 150, and some corresponding characteristics of packaging models 160, 170a, 170b, and 180 to illustrate more clearly various comparisons and considerations that can be Methods for selecting a particular item arrangement.
Layout D, Dy D, Volume Area weight / (inch) (inch) (inch) Surface (feet ') (Lb) Packaging (feetS2) 130/160 20 30 15 27.1 5.21 19 140a / 170a 12 13.5 10 9.2 0, 94 9, 5 - 140b / 170b 25 27 13 31.1 5, 08 9, 5 150/180 10 37 25 '25, 5 5.35 19 TABLE 1 As will be evaluated From an analysis of Table 1 in view of the description here, each provision identified may include several advantages that may become desired over other provisions. Furthermore, although three basic provisions are illustrated, this merely serves to avoid unnecessarily obscuring the invention, and many different provisions can be produced and compared.
In relation to the attributes of the layout arrangements identified in Table 1, it can easily be seen that layout 130 can be selected instead of layout
140a, 140b and 150 (for example, by the packaging custody mechanism 12), particularly if a constraint considered is the desire to reduce the volume of a package. Specifically, the volume of layout 130 is 5 less than the volume of the same items in the layout of items in layout 150, and significantly less than the combined volume of layout 140a, 140b needed to contain the same items.
The total volume can be considered when, for example, it is desired to minimize the amount of empty space in a customized packaging. The reduction of empty space in a package can reduce the amount of displacement or performance between the items contained, and can provide a more precise adjustment than other alternatives.
This can be significant since moving items can cause damage to the items themselves, or to the packaging itself, this could result in damage to other items.
In addition, by reducing the amount of empty space, the need for internal flush materials can be reduced or eliminated. Reducing the volume of packaging, however, may not always translate into reduced cost, or may not always be desired for other reasons. For example, as shown in Table 1, the total weight of the arrangement 130 can be approximately nineteen pounds. Based on shipping, handling, and / or shipping fees, the cost of shipping a nineteen-pound package possibly exceeds the cost of shipping two lightweight packages that contain the same items. Consequently, based on shipping rates, a seller or manufacturer may prefer a provision such as provisions 140a, 140b where the items are distributed between two packages of less than weight. However, the weight does not need to be evenly distributed. Consequently, in an example, the packaging customization mechanism 12 evaluates each arrangement 130, 140a, 140b, and 150 and can select arrangements 140a, 140b based on a desire to reduce handling costs. This selection can be automatic or it can be based on some part of a user's suggestion or selection.
Costs may also, in some circumstances, be reduced by customizing the packaging for provision 150 over any of provisions 130, 140a, and / or 140b. For example, many vendors or manufacturers may use packaging machines to produce a customized packaging, but prefer to avoid the capital expenditure required to purchase that machine. In such cases, companies that specialize in packaging equipment can supply equipment to a seller or manufacturer, and the cost of using the equipment can be based on the amount of corrugated cardboard or other packaging material used to produce packaging models. In that case, a seller, manufacturer, or other person or entity that packs items can experience considerable cost savings by reducing the amount of material used to produce the packaging materials themselves.
When the quantity of packaging materials used is the main concern, a person or entity may associate a weight value with the surface area of the packaging itself as the only relevant restriction, or possibly greater than other restrictions that are also considered. In that case, the arrangement 150 may be preferred as it provides approximately six percent savings on the amount of material used for the disposal package 130, and approximately thirty-seven percent savings on the amount of material used for the arrangement. packaging of provisions 140a, 140b.
The selection of any item arrangement, and the corresponding custom packaging, can be based on the identified criteria or any other desired criteria, and the required cost does not always need to be considered to select a particular arrangement for use with the customized packaging. Furthermore, in some modalities, - the selection of a particular arrangement is carried out automatically, so that from the moment that a set of items is received until the moment that an arrangement of items is identified and / or selected, no human intervention or Annual is necessary to determine the disposition that should be used, or the model of enibalagem that should be produced. In other modalities, however, the selection of a disposition can be entered manually (for example, by an operator of a customized packaging system). For example, various layouts and / or features of layouts and custom packaging can be displayed or otherwise provided to an operator, to allow the operator to select the preferred layout.
Although the previous discussion referred to the custody of a box for a particular order or other item collection, it should be assessed that the described methods can also be easily adapted for other uses. For example, according to one modality, the packaging customization mechanism cannot be connected to a packaging production machine. In fact, a seller, manufacturer, or other person or entity that wants to pack a collection of one or more items can provide this information. When the information about the objects is received in the packaging customization mechanism, it can access the information repository, arrange the items and / or obtain the dimensions of the arrangement. So, instead of creating a packaging template or sending the dimensions to a packaging production machine, the packaging customization mechanism can access information about boxes of different sizes that are already available.
As will be assessed in view of the description here, many different sizes of standard boxes may be available. If items are selected and placed manually, the person placing the items manually can select a box that is too small, and thus spend effort trying to make the items fit within a particular box. The person can also select an appropriately sized box; however, the person can waste valuable time trying to figure out how to adjust all the items in the box.
Due to the time it may take to select a very small box or an appropriately sized box, the person can instead select from a box intentional, or even non-intentional, a box that is larger - and in some cases much larger - than necessary for the items. Using a larger box can reduce the time required to pack items in the box, but it can increase shipping costs, the cost of materials in the box itself, and the cost of internal packaging materials, and the risk of damage and loss of the items contained.
Consequently, although one embodiment of the invention relates to the cutting of a package specifically customized for particular items, another modality relates to the identification which among a variety of boxes already available is more suitable for collecting items. The box can be identified by the packaging customization mechanism, and a model of the standard item layout can also be provided to allow efficient packaging of the box or other packaging.
The discussion here refers to numerous methods and steps of the method and actions that can be taken. It should be noted that although the steps of the method and actions can be discussed in a particular order or illustrated in a flow chart as a particular order occurs, no particular order is necessarily required unless specifically determined, or required due to the fact of an action be dependent.and another action that was completed before the action was performed.
The embodiments of the present invention may comprise or use a special-purpose or general-purpose computer that includes computer hardware, such as, for example, one or more processors and system memory, as discussed in more detail below. The embodiments within the scope of the present invention also include physical and other computer-readable means for transmitting or storing computer-executable instructions and / or data structures. These readable computer inputs can be any available means that can be accessed by a general purpose or special use computer system. Computer readable media that store computer-executable instructions are physical media. Computer readable means that transmit instructions executable by computer are means of transmission. Thus, by way of example, and without limitation, the modalities of the invention can at least comprise two different types of computer-readable media, including at least one computer storage medium and one transmission medium.
Examples of computer storage media include RAM, ROM, EEPROM, CD-ROM or other optical disk storage, magnetic disk storage or other magnetic storage devices, or any other medium that can be used to store code media programs in the form of instructions executable by computer or data structures and which can be accessed by a general-purpose or special-use computer. A "network" is defined as one or more data links that allow the transport of electronic data between computer systems and / or modules, mechanisms, and / or other 5 electronic devices. When information is transferred or provided via a network or other communication connection (by hardwire, wireless, or a combination of hardwire or wireless) to a computer, the computer properly views the connection as a means of transmission. The means of transmission can include a network and / or data links that can be used for transmission or desired program code means in the form of instructions executable by computer or data structures and which can be accessed by a general purpose computer or special use. Combinations of these should also be included within the scope of computer-readable networks.
In addition, by obtaining various components of the computer system, program code media in the form of instructions executable by computer or data structures can be transferred automatically from transmission media to computer storage media (or vice versa) . For example, instructions executable by computer or data structures received over a network or data link can be buffered in RAM inside a network interface module (for example, a "NIC"), and then eventually transferred for computer system RAM and / or for volatile computer storage media in a computer system. Therefore, it must be understood that computer storage media can be included in computer system components that also (or even mainly) use transmission media.
5 Executable computer instructions include, for example, instructions and data that, when executed on a processor, cause a general-purpose computer, special-purpose computer, or special-purpose processing device to perform a particular function or group of tasks. functions. The instructions executable by computer can be, for example, binary instructions, of intermediate format like machine language, or even source code. Although the subject is described in a specific language for structural characteristics and / or methodological actions, it will be understood that the subject in question defined in the attached claims is not necessarily limited to the described characteristics or actions described above, nor the performance of the described actions or steps components described above. Preferably, the described features and actions are revealed as ways to implement the claims.
Elements skilled in the art will appreciate that the invention can be practiced in network computing environments with many types of computer system configurations, including personal computers, desktop computers, laptops, message processors, portable devices, multiprocessor systems. , programmable or microprocessor-based consumer electronics, network PCS, minicomputers, mainframe computers, cell phones, PDAS, pagers, routers, switches, and the like. The invention can also be practiced in distributed system environments where local and remote computer systems are connected (by hardwire data links, wireless data links, or by a combination of hardwire and wireless data links ) over a network, we can perform tasks. In a distributed computing environment, program modules can be located on local and remote memory storage devices.
The elements versed in the technique will also evaluate that the invention can be practiced on special-purpose computing devices or other integrated or coupled to packaging machines, either through a network connection, wireless connection, or hardwire connection. Exemplary packaging machines may include machines that cut or bend packaging materials to form the packaging models. Exemplary packaging machines suitable for use with the modalities of the present invention can also directly or indirectly execute a program code that allows the packaging machine to accept dimensional inputs and design a customized packaging model based on the input. This input can be provided manually or, as described here, it can be provided by a packaging customization mechanism that, for example, automatically determines the required dimensions. In some modalities, the packaging customization mechanism can also be incorporated into the packaging machine that cuts the customized packaging models, while in other modalities these separate from the packaging machine and are communicatively coupled to this one.
Although the prior invention has been described in more detail by way of illustration and example, for the sake of clarity and understanding, some changes and modifications will become obvious to those skilled in the art in view of the description here. The described fashions will be considered in all respects only as illustrative and not restrictive. For example, the frame structures described here act as a fastening structure and can take a variety of shapes, including articulated connections, expandable balloons, multi-layer coils, and the like. Thus, all a3 changes that are in the meaning and equivalence range of the claims will be adopted within its scope.

权利要求:
Claims (15)
[1]
1. Method for creating a customized package on demand, and fixed by the fact that the method comprises: 5 identifying one or more items that will be included in a package; access an informational repository and retrieve, for each said one or more items, the dimensional information about said one or more items; arranging said one or more items in an inmodel arrangement, I err that the disposition of said one or more items is carried out using said dimensional information retrieved from said informational repository; and calculating the dimensions of said model arrangement usable to produce a customized packaging model sized particularly for said one or more items when said one or more items are arranged and positioned according to said model arrangement.
[2]
2. Method, according to claim 1, characterized by the fact that the method additionally includes: receiving a request from said one or more items.
[3]
3. Method, according to claim 2, characterized by the fact that it additionally comprises: designing a packaging model based on said calculated dimensions of said model arrangement of said one or more items.
[4]
4. Method according to any one of claims 1 to 3, characterized by the fact that it further comprises: sending said dimensions to a packaging machine of the right packaging production machine in order to design a packaging model based on said calculated dimensions of said model arrangement.
[5]
5. Method, according to claim 4, characterized by the fact that the optimization of said model arrangement includes evaluating said model arrangement using one or more between: volume of the one or more items; volume of said model arrangement; surface area of the customized packaging right; shipping, transportation or handling costs; or greater minimum size.
[6]
6. Method, according to claim 5, characterized by the fact that the disposition of said one or more items erodes an inclusive model arrangement: producing a plurality of models arrangement; select a particular model layout; and calculate the dimensions of the particular model layout.
[7]
7. Method, according to claim 1, characterized by the fact that said repository of information identifies: dimensions of said one or more items; if said one or more items may have other items nested; and when an item can be nested with other items, dimensions of a nesting area.
[8]
8. One or more computer-readable means are depreciated by the fact that they have stored in these instructions executable by computer which, when executed by a processor, do with. that a computer system performs the method of claim 1.
[9]
9. Packaging machine equipped to carry out the method, according to any one of claims 1 to 7, or in communication with a customization mechanism that carries out the method according to any one of claims 1 to 7, characterized by the fact that the packaging machine is additionally configured to produce a packaging model that corresponds to the calculated dimensions of said model arrangement.
[10]
10. System for creating and customizing on-demand packaging, characterized by the fact that it comprises: one or more means of computer storage that have a repository of information stored in those that include dimension attributes for multiple different items; and an enibalization customization mechanism coupled in a communicative way to said information repository, and said packaging customization mechanism is configured to: receive a customized packaging request for a plurality of items, each said plurality of items is identified in the said information repository; access c) said information repository and recover said dimensional attributes for each said item pIurality; use said dimensional attributes to develop a model arrangement of all among said plurality of items; and calculating the total dimensions of said model arrangement.
[11]
11. System, according to claim 10, characterized by the fact that said packaging customization mechanism is additionally configured to design a packaging model based on said total dimensions of said model arrangement.
[12]
12. Method according to any of claims 10 and 11, characterized by the fact that the use of said dimensional attributes to develop a model arrangement includes using three-dimensional information from said information repository to develop a three-dimensional model arrangement.
[13]
13. Box design on demand and production system that automatically creates customized boxes for any collection of items, characterized by the fact that the system comprises: one or more processors; at least one computer-readable storage medium that provides a repository of dimensional attribute information for different items, the dimensional attributes of which include three-dimensional size information about different items;
a packaging customization mechanism executable by one or more processors to:
receive a request that a plurality of items should be packaged, each between said pIurality
5 of items have corresponding dimensional information stored in said information repository;
access said repository of information and retrieve the information of three-dimensional size about each among said plurality of items;
optimizing a model layout of said plurality of items, wherein optimization of said model layout includes using said three-dimensional layout information from said plurality of items to develop a virtual model that includes each one between said plurality of items;
calculate the dimensions of said virtual model using said information of three-dimensional size of said plurality of items; and perform one of the following:
transmitting said calculated dimensions to a packaging production machine for the design of a box model sized to accommodate the plurality of items when the plurality of items is physically positioned correspondingly to the virtual model;
or design a box model sized to accommodate the plurality of items when the plurality of items is physically positioned correspondingly to the virtual model.
[14]
14. The system, according to claim 13, is characterized by the fact that the on-demand box design and production system additionally include an operable packaging production machine to create 5 packaging models from corrugated cardboard.
[15]
15. The system, according to any one of claims 13 and 14, characterized by the fact that the optimization of this model arrangement automatically includes: producing multiple arrangements; and selecting a particular model arrangement that satisfies the desired restrictions.

类似技术:

---

公开号 | 公开日 | 专利标题

---

BR112013002654A2|2020-10-06|on-demand packaging creation based on stored attribute data

---

BR112012014153A2|2020-05-19|custom packaging creation based on custom item arrangements

---

BR112013014895B1|2020-12-01|system to produce customized packaging on demand

---

EP2588302B1|2020-03-04|Optimizing production of packaging products

---

JP6893530B2|2021-06-23|Tiling production of packaging materials

---

US10402890B2|2019-09-03|Box-last packaging system, method, and computer program product

---

TW201307175A|2013-02-16|Generation of plans for loading and unloading a container

---

US9818070B2|2017-11-14|Tiling production of packaging materials

---

JP2019523184A|2019-08-22|Computerized packaging wall

---

EP3201092B1|2019-05-22|Box-last packaging system

---

RU2574966C2|2016-02-10|Creation of packing by customer request on basis of saved attribute data

---

Wyman et al.2021|A Framework for Mesh-Geometry Associativity during Mesh Adaptation

---

KR20220004353A|2022-01-11|Program for Operation of the fulfillment Optimization Service System

---

KR20220004329A|2022-01-11|Recording Medium

---

KR20220004331A|2022-01-11|Recording Medium

---

Kalita et al.2021|Influence of Stiffeners for Improving the Compressive Strength of Ventilated Corrugated Packages Using Finite Element Modelling Technique

同族专利:

---

公开号 | 公开日

---

EP2601575A1|2013-06-12|

---

JP5795066B2|2015-10-14|

---

WO2012018859A1|2012-02-09|

---

US9914278B2|2018-03-13|

---

CN103210370A|2013-07-17|

---

US20140067104A1|2014-03-06|

---

RU2013109366A|2014-09-10|

---

EP2601575A4|2014-03-05|

---

JP2013539103A|2013-10-17|

---

CN103210370B|2017-02-15|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US5430831A|1991-03-19|1995-07-04|Koninklijke Ptt Nederland N.V.|Method of packing rectangular objects in a rectangular area or space by determination of free subareas or subspaces|

---

JP3554491B2|1998-09-29|2004-08-18|本田技研工業株式会社|Packaging and packaging dimension setting device for multiple products|

---

WO2000046728A2|1999-02-08|2000-08-10|United Parcel Service Of America, Inc.|Internet package shipping systems and methods|

---

US6615104B2|2001-05-01|2003-09-02|Nintendo Of America, Inc.|System and method of selecting box size|

---

US7366643B2|2003-03-20|2008-04-29|Delphi Technologies, Inc.|System, method, and storage medium for determining a packaging design for a container|

---

AU2002323545A1|2001-08-31|2003-03-18|Solidworks Corporation|Simultaneous use of 2d and 3d modeling data|

---

JP2003175918A|2001-12-13|2003-06-24|Toppan Printing Co Ltd|System, method and program for selecting packing configuration|

---

US20030200111A1|2002-04-19|2003-10-23|Salim Damji|Process for determining optimal packaging and shipping of goods|

---

JP2006185207A|2004-12-28|2006-07-13|Boxboost:Kk|Method for ordering corrugated fiberboard box|

---

JP2007047858A|2005-08-05|2007-02-22|Toyota Motor Corp|Article storage examination system and program|

---

US7647752B2|2006-07-12|2010-01-19|Greg Magnell|System and method for making custom boxes for objects of random size or shape|

---

US8340812B1|2007-08-30|2012-12-25|Amazon Technologies, Inc.|Optimization of packaging sizes|

---

US8830223B2|2008-05-08|2014-09-09|Esko Software Bvba|Computer aided design of three-dimensional cartons with curved creases|

---

US7788883B2|2008-06-19|2010-09-07|Xerox Corporation|Custom packaging solution for arbitrary objects|

---

US9493024B2|2008-12-16|2016-11-15|Xerox Corporation|System and method to derive structure from image|

---

US8775130B2|2009-08-27|2014-07-08|Xerox Corporation|System for automatically generating package designs and concepts|

---

US8261983B2|2009-12-17|2012-09-11|Amazon Technologies, Inc.|Generating customized packaging|

---

BR112013002654A2|2010-08-03|2020-10-06|Packsize, Llc|on-demand packaging creation based on stored attribute data|US8340812B1|2007-08-30|2012-12-25|Amazon Technologies, Inc.|Optimization of packaging sizes|

---

US8908995B2|2009-01-12|2014-12-09|Intermec Ip Corp.|Semi-automatic dimensioning with imager on a portable device|

---

BR112013002654A2|2010-08-03|2020-10-06|Packsize, Llc|on-demand packaging creation based on stored attribute data|

---

US9818070B2|2011-07-22|2017-11-14|Packsize Llc|Tiling production of packaging materials|

---

US20130218799A1|2012-02-16|2013-08-22|Sebastian Lehmann|Container Selection in a Materials Handling Facility|

---

US10118723B2|2012-03-23|2018-11-06|Amazon Technologies, Inc.|Custom containers in a materials handling facility|

---

US9779546B2|2012-05-04|2017-10-03|Intermec Ip Corp.|Volume dimensioning systems and methods|

---

US10007858B2|2012-05-15|2018-06-26|Honeywell International Inc.|Terminals and methods for dimensioning objects|

---

US9315344B1|2012-07-20|2016-04-19|Amazon Technologies, Inc.|Container stacking configurations|

---

US9926131B1|2012-07-20|2018-03-27|Amazon Technologies, Inc.|Custom container stacking configurations|

---

US10321127B2|2012-08-20|2019-06-11|Intermec Ip Corp.|Volume dimensioning system calibration systems and methods|

---

US9939259B2|2012-10-04|2018-04-10|Hand Held Products, Inc.|Measuring object dimensions using mobile computer|

---

US9841311B2|2012-10-16|2017-12-12|Hand Held Products, Inc.|Dimensioning system|

---

US9314986B2|2012-10-31|2016-04-19|Xerox Corporation|Method and system for applying an adaptive perforation cut to a substrate|

---

US9245209B2|2012-11-21|2016-01-26|Xerox Corporation|Dynamic bleed area definition for printing of multi-dimensional substrates|

---

CN105229681B|2013-01-18|2020-12-29|派克赛泽有限责任公司|Splicing production of packaging materials|

---

WO2016176278A1|2015-04-29|2016-11-03|Packsize Llc|Tiling production of packaging materials|

---

US10922637B2|2013-01-18|2021-02-16|Packsize Llc|Tiling production of packaging materials|

---

US9460056B2|2013-01-22|2016-10-04|Xerox Corporation|Dynamic image layout for personalized packages|

---

US9080856B2|2013-03-13|2015-07-14|Intermec Ip Corp.|Systems and methods for enhancing dimensioning, for example volume dimensioning|

---

US20140336027A1|2013-05-13|2014-11-13|Xerox Corporation|System and method for creating customized boxes|

---

US20140358600A1|2013-05-30|2014-12-04|Oracle International Corporation|Item placement optimizer|

---

US10228452B2|2013-06-07|2019-03-12|Hand Held Products, Inc.|Method of error correction for 3D imaging device|

---

EP3461751B1|2013-08-05|2021-03-31|Packsize LLC|Packaging material as a pick item|

---

US9464885B2|2013-08-30|2016-10-11|Hand Held Products, Inc.|System and method for package dimensioning|

---

US20150120599A1|2013-10-31|2015-04-30|International Business Machines Corporation|Partner Marketing and Order Fulfillment Based on Partner Merchant Shipping Efficiencies|

---

JP5540164B1|2014-01-08|2014-07-02|株式会社ディー・エヌ・エー|Product sales processing system|

---

US9916399B2|2014-05-05|2018-03-13|Xerox Corporation|Dynamic optimization of detailed flat design based on desired final structural attributes|

---

US10546264B2|2014-05-16|2020-01-28|United Parcel Service Of America, Inc.|Systems, methods, and computer program products for consolidated identification and engagement of on-demand packaging customers|

---

US20150379462A1|2014-06-27|2015-12-31|Pregis Innovative Packaging Llc|Protective packaging system consumable resupply system|

---

US9823059B2|2014-08-06|2017-11-21|Hand Held Products, Inc.|Dimensioning system with guided alignment|

---

US10775165B2|2014-10-10|2020-09-15|Hand Held Products, Inc.|Methods for improving the accuracy of dimensioning-system measurements|

---

US10810715B2|2014-10-10|2020-10-20|Hand Held Products, Inc|System and method for picking validation|

---

US9779276B2|2014-10-10|2017-10-03|Hand Held Products, Inc.|Depth sensor based auto-focus system for an indicia scanner|

---

US9557166B2|2014-10-21|2017-01-31|Hand Held Products, Inc.|Dimensioning system with multipath interference mitigation|

---

US10060729B2|2014-10-21|2018-08-28|Hand Held Products, Inc.|Handheld dimensioner with data-quality indication|

---

US9762793B2|2014-10-21|2017-09-12|Hand Held Products, Inc.|System and method for dimensioning|

---

US9897434B2|2014-10-21|2018-02-20|Hand Held Products, Inc.|Handheld dimensioning system with measurement-conformance feedback|

---

US9752864B2|2014-10-21|2017-09-05|Hand Held Products, Inc.|Handheld dimensioning system with feedback|

---

US20180297266A1|2014-12-17|2018-10-18|X Development Llc|Actuated Molding Device for Construction of Packaging Structures|

---

US9828128B1|2014-12-17|2017-11-28|X Development Llc|On-demand protective structures for packaging items in a container|

---

US9840347B1|2014-12-17|2017-12-12|X Development LLX|Adhering modular elements for packaging structures|

---

US9536216B1|2014-12-18|2017-01-03|Amazon Technologies, Inc.|Delivery of packages by unmanned aerial vehicles|

---

US9639824B1|2014-12-22|2017-05-02|Amazon Technologies, Inc.|Dynamically-sized containers for inventory system|

---

US9786101B2|2015-05-19|2017-10-10|Hand Held Products, Inc.|Evaluating image values|

---

US10066982B2|2015-06-16|2018-09-04|Hand Held Products, Inc.|Calibrating a volume dimensioner|

---

US9857167B2|2015-06-23|2018-01-02|Hand Held Products, Inc.|Dual-projector three-dimensional scanner|

---

US20160377414A1|2015-06-23|2016-12-29|Hand Held Products, Inc.|Optical pattern projector|

---

US9835486B2|2015-07-07|2017-12-05|Hand Held Products, Inc.|Mobile dimensioner apparatus for use in commerce|

---

EP3396313B1|2015-07-15|2020-10-21|Hand Held Products, Inc.|Mobile dimensioning method and device with dynamic accuracy compatible with nist standard|

---

US20170017301A1|2015-07-16|2017-01-19|Hand Held Products, Inc.|Adjusting dimensioning results using augmented reality|

---

US10094650B2|2015-07-16|2018-10-09|Hand Held Products, Inc.|Dimensioning and imaging items|

---

US9619775B1|2015-09-17|2017-04-11|Shu Saito|Machine learning for determination of shipping rules and shipping methods for order fulfillment|

---

EP3147838A1|2015-09-23|2017-03-29|Neopost Technologies|Parcel packaging method and device|

---

US10249030B2|2015-10-30|2019-04-02|Hand Held Products, Inc.|Image transformation for indicia reading|

---

US10225544B2|2015-11-19|2019-03-05|Hand Held Products, Inc.|High resolution dot pattern|

---

US10235653B1|2015-12-08|2019-03-19|Amazon Technologies, Inc.|Packing locations for inventory items|

---

US10227171B2|2015-12-23|2019-03-12|Pregis Intellipack Llc|Object recognition for protective packaging control|

---

DE102016100133A1|2016-01-05|2017-07-06|Deutsche Post Ag|Method for producing a padding|

---

US10025314B2|2016-01-27|2018-07-17|Hand Held Products, Inc.|Vehicle positioning and object avoidance|

---

EP3200036B1|2016-01-29|2020-09-02|Quadient Technologies France|Method and apparatus for optimizing automated packaging|

---

US10687683B2|2016-03-24|2020-06-23|Martin A. Alpert|Washing or washing/sterilizing and drying or drying/sterilizing with optional independent sterilization apparatus with robotic arms|

---

KR101869946B1|2016-03-31|2018-06-21|쿠팡 주식회사|Control system for packaging delivery article and controlling method for packaging delivery article|

---

US10339352B2|2016-06-03|2019-07-02|Hand Held Products, Inc.|Wearable metrological apparatus|

---

US9940721B2|2016-06-10|2018-04-10|Hand Held Products, Inc.|Scene change detection in a dimensioner|

---

US10163216B2|2016-06-15|2018-12-25|Hand Held Products, Inc.|Automatic mode switching in a volume dimensioner|

---

EP3284687B1|2016-08-16|2020-11-04|Quadient Technologies France|System and method for automatically packaging items varying in size and number for shipment|

---

DE102016120406A1|2016-10-26|2018-04-26|Deutsche Post Ag|A method of determining a charge for sending a shipment|

---

US11092946B2|2016-12-01|2021-08-17|Packsize Llc|Identifying and managing equipment within an operational environment|

---

US10909708B2|2016-12-09|2021-02-02|Hand Held Products, Inc.|Calibrating a dimensioner using ratios of measurable parameters of optic ally-perceptible geometric elements|

---

EP3354581B1|2017-01-31|2021-05-19|Quadient Technologies France|System and method for automating packaging of varying shipment sets|

---

US10586379B2|2017-03-08|2020-03-10|Ebay Inc.|Integration of 3D models|

---

US20180265228A1|2017-03-16|2018-09-20|Lukas Hagestedt|Dunnage and packaging optimization|

---

US11047672B2|2017-03-28|2021-06-29|Hand Held Products, Inc.|System for optically dimensioning|

---

US10961053B2|2018-03-30|2021-03-30|Fastfetch Corporation|Light assisted pack wall carton selection and replenishment system|

---

US10642551B2|2017-07-14|2020-05-05|Georgia-Pacific Corrugated Llc|Engine for generating control plans for digital pre-print paper, sheet, and box manufacturing systems|

---

US10733748B2|2017-07-24|2020-08-04|Hand Held Products, Inc.|Dual-pattern optical 3D dimensioning|

---

CN111448069B|2017-08-31|2022-02-25|通用电气公司|Distribution of customized engineering models for additive manufacturing|

---

CN107679795A|2017-09-26|2018-02-09|深圳市行云易通科技有限公司|A kind of method of article manner of packing selection|

---

US10584962B2|2018-05-01|2020-03-10|Hand Held Products, Inc|System and method for validating physical-item security|

---

CN109373893A|2018-08-30|2019-02-22|福建省汽车工业集团云度新能源汽车股份有限公司|A kind of method and storage equipment of calculating object package size|

---

CN109250233A|2018-09-18|2019-01-22|珠海格力电器股份有限公司|The packing method and device of object to be packaged|

---

US10970654B2|2018-10-18|2021-04-06|International Business Machines Corporation|Appropriately distributing items using augmented reality|

---

CN109625390B|2018-12-21|2021-05-18|佛山市南海区微高软件有限公司|Window part subpackaging method and device, storage medium and terminal equipment|

---

CN109781407B|2019-03-08|2020-07-07|西继迅达电梯有限公司|Traction machine loading test platform|

---

EP3832558A1|2019-12-06|2021-06-09|Manyfolds UG |Method of cartoning|

---

US20210350037A1|2020-05-08|2021-11-11|Esko Software Bvba|Method and system for deriving a digital representation of an unfolded blank and for cost estimation based upon the same|

---

EP3944163A1|2020-07-20|2022-01-26|Siemens Aktiengesellschaft|Method and systems for optimizing logistics|

---

CN113361806A|2021-06-30|2021-09-07|嘉兴聚水潭电子商务有限公司|Recommendation method and system for calculating order use consumables|

法律状态:
2020-10-13| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

---

2021-02-23| B07A| Application suspended after technical examination (opinion) [chapter 7.1 patent gazette]|

---

2021-06-29| B09B| Patent application refused [chapter 9.2 patent gazette]|

---

2021-09-14| B09B| Patent application refused [chapter 9.2 patent gazette]|Free format text: MANTIDO O INDEFERIMENTO UMA VEZ QUE NAO FOI APRESENTADO RECURSO DENTRO DO PRAZO LEGAL |

---

2021-11-23| B350| Update of information on the portal [chapter 15.35 patent gazette]|

优先权:

---

申请号 | 申请日 | 专利标题

---

US37040210P| true| 2010-08-03|2010-08-03|

---

US61/370,402|2010-08-03|

---

PCT/US2011/046327|WO2012018859A1|2010-08-03|2011-08-02|Creating on-demand packaging based on stored attribute data|

---