Abstract: An intelligent load control device is provided for operable incorporation in an object. The intelligent load control device includes devices disposed about the object to detect characteristics thereof that are relevant to an object tipping event, a response system, and a processing unit. The response system is configured to take an action to mitigate risks associated with the object tipping event responsive to received control instructions. The processing unit is disposed to be receptive of the detected characteristics from the devices and to issue the control instructions to the response system. The processing unit is configured to dynamically analyze the detected characteristics to determine a likelihood of the object tipping event and to issue the control instructions in accordance with the determined likelihood.

Abstract: A system and a method for stability measurement and optimization are provided. For example, the method includes loading an object onto a tilting device that includes one or more sensor devices, collecting resting corner weight values from the one or more sensor devices, tilting the object using the tilting device, collecting tilted corner weight values from the one or more sensor devices while tilting the object using the tilting device, calculating, using a data processor of the tilting device, a center of gravity value based on the resting corner weight values, the tilted corner weight values, and dimensions of the object, generating, using the data processor, a tipping angle based on at least the center of gravity value and the dimensions of the object, and generating, using the data processor, a recommendation to adjust the tipping angle.

Abstract: An intelligent load control device is provided for operable incorporation in an object. The intelligent load control device includes devices disposed about the object to detect characteristics thereof that are relevant to an object tipping event, a response system, and a processing unit. The response system is configured to take an action to mitigate risks associated with the object tipping event responsive to received control instructions. The processing unit is disposed to be receptive of the detected characteristics from the devices and to issue the control instructions to the response system. The processing unit is configured to dynamically analyze the detected characteristics to determine a likelihood of the object tipping event and to issue the control instructions in accordance with the determined likelihood.

Abstract: An intelligent load control device is provided for operable incorporation in an object. The intelligent load control device includes devices disposed about the object to detect characteristics thereof that are relevant to an object tipping event, a response system, and a processing unit. The response system is configured to take an action to mitigate risks associated with the object tipping event responsive to received control instructions. The processing unit is disposed to be receptive of the detected characteristics from the devices and to issue the control instructions to the response system. The processing unit is configured to dynamically analyze the detected characteristics to determine a likelihood of the object tipping event and to issue the control instructions in accordance with the determined likelihood.

Abstract: An intelligent load control device is provided for operable incorporation in an object. The intelligent load control device includes devices disposed about the object to detect characteristics thereof that are relevant to an object tipping event, a response system, and a processing unit. The response system is configured to take an action to mitigate risks associated with the object tipping event responsive to received control instructions. The processing unit is disposed to be receptive of the detected characteristics from the devices and to issue the control instructions to the response system. The processing unit is configured to dynamically analyze the detected characteristics to determine a likelihood of the object tipping event and to issue the control instructions in accordance with the determined likelihood.

Abstract: A system and a method for stability measurement and optimization are provided. For example, the method includes loading an object onto a tilting device that includes one or more sensor devices, collecting resting corner weight values from the one or more sensor devices, tilting the object using the tilting device, collecting tilted corner weight values from the one or more sensor devices while tilting the object using the tilting device, calculating, using a data processor of the tilting device, a center of gravity value based on the resting corner weight values, the tilted corner weight values, and dimensions of the object, generating, using the data processor, a tipping angle based on at least the center of gravity value and the dimensions of the object, and generating, using the data processor, a recommendation to adjust the tipping angle.

Abstract: The present invention provides a method for shipping products that include (a) sending requests for quotations by electronic transmission to a plurality of selected carriers based upon customer order specifications, available delivery options and a carrier quality database; (b) selecting a carrier quotation based upon quotations received by electronic transmission and the carrier quality database and updating the carrier quality database with the selected carrier and quotation; (c) preparing the product shipment including using an optical scanner to measure shipment dimensions and a weight scale to measure shipment weight of the product shipment; and (d) if the measured dimensions and weight do not conform to the selected quotation, repeating steps (b) and (c) with measured shipment dimensions and weight or, if the measured dimensions and weight do conform to the selected quotation, notifying carrier to ship the product.

Abstract: Embodiments of the present invention provide a method, system and computer program product for real-time multi-lingual adaptation of manufacturing instructions in a manufacturing management system. In one embodiment of the invention, a manufacturing language adaptation method can be provided. The method can include identifying an operator receiving manufacturing instruction, determining a primary language preference for the operator and determining whether or not the manufacturing instructions have been translated into the primary language preference. If it is determined that the manufacturing instructions have been translated into the primary language preference, the manufacturing instructions can be presented to the operator in the primary language preference. Otherwise the manufacturing instructions can be submitted to a translation engine for translation into the primary language preference.

Abstract: A system for performing a part inventory analysis is provided. In response to determining a current part inventory, current order demands on the current part inventory are determined. The current part inventory is segmented. An order demand coverage is determined for each segment of the segmented inventory based on the current order demands. A conditioned part inventory is determined based on a loaner part inventory analysis of the segmented inventory. A part purchase recommendation is calculated based on the conditioned part inventory. Then, data for the segmented inventory, the order demand coverage, the conditioned part inventory, and the part purchase recommendation are stored in a storage device.

Abstract: Automated techniques for identifying packaging solutions, where a dynamic, automated decision is made as to whether items are to be bulk packed and/or whether particular containers are to be bulk cased (that is, consolidated within casing such as pallets). Factors considered may comprise customer-specific requests, order destination, type of items, quantity of items, size of items, quantity of grouped orders, size of grouped orders, and so forth. Orders may contain items that are alike as well as items that are different from one another. A particular order or orders may be assembled as the items of the order(s) arrive for packaging, without requiring a fixed timing or sequence of item arrival, thereby providing a dynamic, real-time packaging solution.

Abstract: A method and apparatus for a pull back optimizer in conjunction with an inventory management system allows for efficient retrieval of return assemblies for optimized parts fulfillment. The inventory management system includes a return assembly inventory and a list of parts needed for order fulfillment. The return assembly inventory lists the part numbers and quantities of parts in each return assembly. The pull back optimizer allows a user of the inventory management system to efficiently determine the optimal return systems to pull back to production for parts fulfillment to minimize the impact on those using the return assemblies.

Abstract: The present invention provides a method for shipping products that include (a) sending requests for quotations by electronic transmission to a plurality of selected carriers based upon customer order specifications, available delivery options and a carrier quality database; (b) selecting a carrier quotation based upon quotations received by electronic transmission and the carrier quality database and updating the carrier quality database with the selected carrier and quotation; (c) preparing the product shipment including using an optical scanner to measure shipment dimensions and a weight scale to measure shipment weight of the product shipment; and (d) if the measured dimensions and weight do not conform to the selected quotation, repeating steps (b) and (c) with measured shipment dimensions and weight or, if the measured dimensions and weight do conform to the selected quotation, notifying carrier to ship the product.

Abstract: Automated techniques for identifying packaging solutions, where a dynamic, automated decision is made as to whether items are to be bulk packed and/or whether particular containers are to be bulk cased (that is, consolidated within casing such as pallets). Factors considered may comprise customer-specific requests, order destination, type of items, quantity of items, size of items, quantity of grouped orders, size of grouped orders, and so forth. Orders may contain items that are alike as well as items that are different from one another. A particular order or orders may be assembled as the items of the order(s) arrive for packaging, without requiring a fixed timing or sequence of item arrival, thereby providing a dynamic, real-time packaging solution.

Abstract: A method and apparatus for a pull back optimizer in conjunction with an inventory management system allows for efficient retrieval of return assemblies for optimized parts fulfillment. The inventory management system includes a return assembly inventory and a list of parts needed for order fulfillment. The return assembly inventory lists the part numbers and quantities of parts in each return assembly. The pull back optimizer allows a user of the inventory management system to efficiently determine the optimal return systems to pull back to production for parts fulfillment to minimize the impact on those using the return assemblies.

Abstract: Embodiments of the present invention provide a method, system and computer program product for multiple-location auto-cascading clear to build inventory management. In an embodiment of the invention, an order processing method can be provided. The order processing method can include determining a required allocation of parts necessary to build an order, recursively soft allocating parts in different locations until enough parts have been soft allocated to satisfy the required allocation of parts necessary to build the order, and hard allocating the soft allocated parts. In one aspect of the embodiment, it can be determined that not enough parts remain amongst the different locations to satisfy the required allocation of parts necessary to build the order. In that circumstance, the soft allocated parts can be cleared for allocation by a different order.

Abstract: Embodiments of the present invention provide a method, system and computer program product for an auto-cascading clear to build (CTB) tool for multiple enterprise parts management. A method for auto-cascading (CTB) for multiple enterprise parts management can include receiving a demand resulting in an inventory requirement to satisfy the demand, soft allocating inventory meeting a portion of the inventory requirement from multiple different intra-plant locations in an order of priority specified by a set of inventory location priority rules, further soft allocating inventory meeting a remaining portion of the inventory requirement from inventory of multiple different external suppliers in an order of priority specified by the set of inventory location priority rules, and hard reserving the soft allocated inventory and updating inventory levels both in each of the intra-plant locations and also in the external suppliers.

Abstract: A system for performing a part inventory analysis. In response to determining a current part inventory, current order demands on the current part inventory are determined. The current part inventory is segmented. An order demand coverage is determined for each segment of the segmented inventory based on the current order demands. A conditioned part inventory is determined based on a loaner part inventory analysis of the segmented inventory. A part purchase recommendation is calculated based on the conditioned part inventory. Then, data for the segmented inventory, the order demand coverage, the conditioned part inventory, and the part purchase recommendation are stored in a storage device.

Abstract: Embodiments of the present invention provide a method, system and computer program product for real-time multi-lingual adaptation of manufacturing instructions in a manufacturing management system. In one embodiment of the invention, a manufacturing language adaptation method can be provided. The method can include identifying an operator receiving manufacturing instruction, determining a primary language preference for the operator and determining whether or not the manufacturing instructions have been translated into the primary language preference. If it is determined that the manufacturing instructions have been translated into the primary language preference, the manufacturing instructions can be presented to the operator in the primary language preference. Otherwise the manufacturing instructions can be submitted to a translation engine for translation into the primary language preference.

Abstract: A computer implemented method, apparatus, and computer usable program code for dynamically creating labels are provided. Fulfillment of customer orders has labeling requirements for which labels must be created. One or more images are selected from a repository of label sub-images based on a customer order to construct a finished label for use with the customer order. Label configurations are identified from a second repository to determine the arrangement of the label sub-images on the label layout. The selected images are arranged according to the label configurations into a single layout of a finished label. The finished label is included with the customer order. Finished labels created in this manner are created according to specific customer orders. This manner of label production uses fewer common types of label stock and eliminates the waste of pre-printed labels when changes are made to a customer order for any reason.