Abstract: In one embodiment, systems and methods include using an ultrasonic cutter in a ground detection system to prevent damage to a substrate. The method of detecting a substrate comprises attaching a workpiece clamp to the substrate. The method further comprises cutting a layer of coating disposed on the substrate with an ultrasonic cutter, wherein the ultrasonic cutter operates at a frequency of about 20 kHz to about 40 kHz, wherein the layer of coating is non-conductive. The method further comprises contacting the substrate with the ultrasonic cutter.

Abstract: In one embodiment, systems and methods include using an ultrasonic cutter in a ground detection system to prevent damage to a substrate. The method of detecting a substrate comprises attaching a workpiece clamp to the substrate. The method further comprises cutting a layer of coating disposed on the substrate with an ultrasonic cutter, wherein the ultrasonic cutter operates at a frequency of about 20 kHz to about 40 kHz, wherein the layer of coating is non-conductive. The method further comprises contacting the substrate with the ultrasonic cutter.

Abstract: In one embodiment, systems and methods include using an ultrasonic cutter in a ground detection system to prevent damage to a substrate. The method of detecting a substrate comprises attaching a workpiece clamp to the substrate. The method further comprises cutting a layer of coating disposed on the substrate with an ultrasonic cutter, wherein the ultrasonic cutter operates at a frequency of about 20 kHz to about 40 kHz, wherein the layer of coating is non-conductive. The method further comprises contacting the substrate with the ultrasonic cutter.

Abstract: In one embodiment, systems and methods include using an ultrasonic cutter in a ground detection system to prevent damage to a substrate. The method of detecting a substrate comprises attaching a workpiece clamp to the substrate. The method further comprises cutting a layer of coating disposed on the substrate with an ultrasonic cutter, wherein the ultrasonic cutter operates at a frequency of about 20 kHz to about 40 kHz, wherein the layer of coating is non-conductive. The method further comprises contacting the substrate with the ultrasonic cutter.

Abstract: A method for processing an order for components includes receiving, at a server, an order that specifies one or more components for procurement and constraints for procuring the one or more components. A processor determines one or more sources capable of providing one or more of the components within the received constraints. At least one of the sources corresponds to a 3D printing facility that prints components via a 3D printing process. The processor communicates one or more orders for procuring the one or more components to the determined one or more sources.

Abstract: A method for routing object data that defines a 3-dimensional (3D) object to a 3D printer includes receiving the object data at a server and determining, by the server, object attributes associated with the object defined by the object data. The server searches a database that stores 3D printer attributes for one or more 3D printers capable of printing objects that possess the determined object attributes. If one or more capable printers are identified, the server communicates a list that identifies the one or more capable printers to a user.

Abstract: A method for routing object data that defines a 3-dimensional (3D) object to a 3D printer includes receiving the object data at a server and determining, by the server, object attributes associated with the object defined by the object data. The server searches a database that stores 3D printer attributes for one or more 3D printers capable of printing objects that possess the determined object attributes. If one or more capable printers are identified, the server communicates a list that identifies the one or more capable printers to a user.

Abstract: A method for routing object data that defines a 3-dimensional (3D) object to a 3D printer includes receiving the object data at a server and determining, by the server, object attributes associated with the object defined by the object data. The server searches a database that stores 3D printer attributes for one or more 3D printers capable of printing objects that possess the determined object attributes. If one or more capable printers are identified, the server communicates a list that identifies the one or more capable printers to a user.

Abstract: Systems (100) and methods (400) for an object (1121) within an area (102). The methods involve: receiving, by a Radio Frequency Identification (“RFID”) tag (1141) coupled to the object, a Radio Frequency (“RF”) interrogator signal transmitted from an RFID reader (108); processing, by the RFID tag, the RF interrogator signal to determine if the RF interrogator signal applies thereto; and performing operations by the RFID tag to direct a person's attention directly to the object by activating at least one alerting mechanism (220) electrically and mechanically coupled to the RFID tag when the RF interrogator signal is determined to apply to the RFID tag. In some scenarios, the alerting is additionally or alternatively performed by a beacon (110).

Abstract: A method for processing an order for components includes receiving, at a server, an order that specifies one or more components for procurement and constraints for procuring the one or more components. A processor determines one or more sources capable of providing one or more of the components within the received constraints. At least one of the sources corresponds to a 3D printing facility that prints components via a 3D printing process. The processor communicates one or more orders for procuring the one or more components to the determined one or more sources.

Abstract: Systems (100) and methods (400) for an object (1121) within an area (102). The methods involve: receiving, by a Radio Frequency Identification (“RFID”) tag (1141) coupled to the object, a Radio Frequency (“RF”) interrogator signal transmitted from an RFID reader (108); processing, by the RFID tag, the RF interrogator signal to determine if the RF interrogator signal applies thereto; and performing operations by the RFID tag to direct a person's attention directly to the object by activating at least one alerting mechanism (220) electrically and mechanically coupled to the RFID tag when the RF interrogator signal is determined to apply to the RFID tag. In some scenarios, the alerting is additionally or alternatively performed by a beacon (110).

Abstract: A method and apparatus for sealing films. In one embodiment the sealing device comprises a horn and an anvil. The film has a standard portion and an increased portion. Increased energy is applied to the film in the increased portion compared to the energy applied to the standard portion. Such a method allows for sealing of varying number of layers.

Abstract: A method and apparatus for sealing films. In one embodiment the sealing device comprises a horn and an anvil. The film has a standard portion and an increased portion. Increased energy is applied to the film in the increased portion compared to the energy applied to the standard portion. Such a method allows for sealing of varying number of layers.

Abstract: A method for routing object data that defines a 3-dimensional (3D) object to a 3D printer includes receiving the object data at a server and determining, by the server, object attributes associated with the object defined by the object data. The server searches a database that stores 3D printer attributes for one or more 3D printers capable of printing objects that possess the determined object attributes. If one or more capable printers are identified, the server communicates a list that identifies the one or more capable printers to a user.

Abstract: A method and apparatus for sealing films. In one embodiment the sealing device comprises a horn and an anvil. The film has a standard portion and an increased portion. Increased energy is applied to the film in the increased portion compared to the energy applied to the standard portion. Such a method allows for sealing of varying number of layers.

Abstract: A method and apparatus for sealing films. In one embodiment the sealing device comprises a horn and an anvil. The film has a standard portion and an increased portion. Increased energy is applied to the film in the increased portion compared to the energy applied to the standard portion. Such a method allows for sealing of varying number of layers.