Abstract: Provided are electric vehicle charging systems and methods of operating such systems for charging electric vehicles (EVs). A system comprises one or more EV charging ports (e.g., charge handles) for connecting to EVs. The system may include various features to identify specific EVs. The system also includes a grid connector for connecting to an external power grid and, in some examples, to monitor the power grid conditions (e.g., voltage, AC frequency). The system also includes a system controller, configured to control the power output at each EV charging port based on, e.g., vehicle charging requirements and/or available grid power. The system can also include an integrated battery, serving as a backup and/or an addition to the power grid. Furthermore, in some examples, the system includes a solar connector (e.g., with an integrated inverter) for connection to an external solar array.

Abstract: Provided are electric vehicle charging systems (EV charging systems) and methods of operating such systems for charging electric vehicles (EVs). A system, which may be referred to as electric vehicle service equipment (EVSE), comprises one or more EV charging ports (e.g., charge handles) for connecting to EVs. The system may include various features to identify specific EVs. The system also includes a grid connector for connecting to an external power grid and, in some examples, to monitor the power grid conditions (e.g., voltage, AC frequency). The system also includes a system controller, configured to control the power output at each EV charging port based on, e.g., vehicle charging requirements and/or available grid power. The system can also include an integrated battery, serving as a backup and/or an addition to the power grid. Furthermore, in some examples, the system includes a solar connector (e.g., with an integrated inverter) for connection to an external solar array.

Abstract: Part retention features are disclosed for securing additively manufactured (AM) parts or for securing an AM part with another component, such as a node, panel, tube, extrusion, and the like, while an adhesive is being applied and/or while the adhesive is undergoing expansion due to a subsequent curing process. The retention features described herein can be used in the context of one or more AM parts such that the elements used to house the retention features (e.g., grooves, apertures, elastic elements, etc.) can advantageously be co-printed with the AM part, thereby removing a manufacturing step. The retention features also can be made with flatter profiles than existing solutions, making the overall structure smaller and less cumbersome to assemble.

Abstract: A high precision Interface Node is disclosed. The Interface Node includes an integrated structure including one or more complex or sophisticated features and functions. The Interface Node may connect with another component or a Linking Node. The Interface Node is manufactured to achieve high precision functionality while enabling volume production. Current additive manufacturing technologies allow for the printing of high precision features to be manufactured, but generally this is performed at a slower rate. Consequently, in one aspect, the size of the Interface Nodes is reduced in order to overcome at least part of the slower production volume caused by creating the high precision Interface Nodes. The components and Linking Nodes to which the Interface Node is connected may only have basic features and functions. Accordingly, this latter category of components may use a high print rate and thus high production volume.

Abstract: Techniques for joining nodes and subcomponents are presented herein. An additively manufactured first node or subcomponent has a groove. An additively manufactured second node or subcomponent has a tongue configured to extend into and mate with the groove to form a tongue-and-groove connection between the first and second node or subcomponent. In some aspects, the tongue-groove connection may extend substantially around a periphery of the node or subcomponent. In other aspects, a first subcomponent having a fluid pipe interface may be coupled via a tongue-groove connection to a second subcomponent having a fluid pipe interface, thereby enabling fluid to flow between subcomponents of the resulting integrated component.

Abstract: A node to panel interface structure for use in a transport structure such as a vehicle is disclosed. In an aspect, the node includes a base, first and second sides protruding from the base to form a recess for receiving a panel, ports for adhesive injection and/or vacuum generation, one or more adhesive regions disposed on a surface of each side adjacent the panel, and at least one channel coupled between the first and second ports and configured to fill the adhesive regions with an adhesive, the adhesive being cured to form a node-panel interface. The node may be additively manufactured. In an exemplary embodiment, the node may use sealant features for including sealants that border and define the adhesive regions, and that may hermetically seal the region before and after adhesive injection. In another embodiment, the node may include isolation features for including isolators for inhibiting galvanic corrosion.

Abstract: Apparatus and methods for additively manufacturing adhesive inlet and outlet ports are presented herein. Adhesive inlet and outlet ports are additively manufactured to include additively manufactured (AM) valves for reducing and/or eliminating sealant leakage and backflow. Robot end effectors are tailored to interface with the AM inlet and outlet ports and to provide an adhesive source and/or a vacuum source. AM inlet and outlet ports enable robust, lightweight, multi-material AM parts connected via adhesive joining.

Abstract: Techniques for flexible, on-site additive manufacturing of components or portions thereof for transport structures are disclosed. An automated assembly system for a transport structure may include a plurality of automated constructors to assemble the transport structure. In one aspect, the assembly system may span the full vertically integrated production process, from powder production to recycling. At least some of the automated constructors are able to move in an automated fashion between the station under the guidance of a control system. A first of the automated constructors may include a 3-D printer to print at least a portion of a component and to transfer the component to a second one of the automated constructors for installation during the assembly of the transport structure. The automated constructors may also be adapted to perform a variety of different tasks utilizing sensors for enabling machine-learning.

Abstract: An additively manufactured node is disclosed. A node is an additively manufactured (AM) structure that includes a feature, e.g., a socket, a receptacle, etc., for accepting another structure, e.g., a tube, a panel, etc. An additively manufactured node can include a surface with an opening to a feed channel through the node. A second surface of the node can include with a plurality of openings to an array of outlet channels. Each of the outlet channels can extend through the node and can connect to the feed channel. Tortuous paths can be used between channels created by the node surface and adjacent structures as well as node interior surfaces. These tortuous paths can be tuned to allow for optimal fluid flow processes.

Abstract: A node may be additively manufactured. The node may include a first surface and a second surface, and the second surface may bound a recess of the node. A structure may be inserted into the recess. A sealing member extend away from the second surface and contact the structure, such that a sealed space may be created between the node and the structure. An adhesive may be applied in the sealed space to at least partially attach the structure to the node.

Abstract: A node including a single port for bonding to various components in a transport structure is disclosed. In an aspect, the node includes an inlet aperture disposed inside the port. The inlet aperture is configured to inject a fluid into at least one region to be filled by the fluid. For example, the fluid can be an adhesive. In another aspect of the disclosure, a nozzle to be interfaced with a single port node is provided. The nozzle includes a first channel to inject the adhesive. The nozzle may further include a second channel and a third channel. In another aspect of the disclosure, a method of using a single port node is provided.

Abstract: An additively manufactured node is disclosed. A node is an additively manufactured (AM) structure that includes a feature, e.g., a socket, a channel, etc., for accepting another structure, e.g., a tube, a panel, etc. The node can include a node surface of a receptacle extending into the node. The receptacle can receive a structure, and a seal interface on the node surface can seat a seal member between the node surface and the structure to create an adhesive region between the node and the structure, the adhesive region being bounded by the node surface, the structure, and the seal member. The node can also include two channels connecting an exterior surface of the node to the adhesive region. In this way, adhesive can be injected into the adhesive region between the node and the structure, and the adhesive can be contained by the seal member.

Abstract: Techniques for flexible, on-site additive manufacturing of components or portions thereof for transport structures are disclosed. An automated assembly system for a transport structure may include a plurality of automated constructors to assemble the transport structure. In one aspect, the assembly system may span the full vertically integrated production process, from powder production to recycling. At least some of the automated constructors are able to move in an automated fashion between the station under the guidance of a control system. A first of the automated constructors may include a 3-D printer to print at least a portion of a component and to transfer the component to a second one of the automated constructors for installation during the assembly of the transport structure. The automated constructors may also be adapted to perform a variety of different tasks utilizing sensors for enabling machine-learning.

Abstract: Provided are electric vehicle charging systems (EV charging systems) and methods of operating such systems for charging electric vehicles (EVs). A system, which may be referred to as electric vehicle service equipment (EVSE), comprises one or more EV charging ports (e.g., charge handles) for connecting to EVs. The system may include various features to identify specific EVs. The system also includes a grid connector for connecting to an external power grid and, in some examples, to monitor the power grid conditions (e.g., voltage, AC frequency). The system also includes a system controller, configured to control the power output at each EV charging port based on, e.g., vehicle charging requirements and/or available grid power. The system can also include an integrated battery, serving as a backup and/or an addition to the power grid. Furthermore, in some examples, the system includes a solar connector (e.g., with an integrated inverter) for connection to an external solar array.

Abstract: An additively manufactured node is disclosed. A node is an additively manufactured (AM) structure that includes a feature, e.g., a socket, a channel, etc., for accepting another structure, e.g., a tube, a panel, etc. The node can include a node surface of a receptacle extending into the node. The receptacle can receive a structure, and a seal interface on the node surface can seat a seal member between the node surface and the structure to create an adhesive region between the node and the structure, the adhesive region being bounded by the node surface, the structure, and the seal member. The node can also include two channels connecting an exterior surface of the node to the adhesive region. In this way, adhesive can be injected into the adhesive region between the node and the structure, and the adhesive can be contained by the seal member.

Abstract: Part retention features are disclosed for securing additively manufactured (AM) parts or for securing an AM part with another component, such as a node, panel, tube, extrusion, and the like, while an adhesive is being applied and/or while the adhesive is undergoing expansion due to a subsequent curing process. The retention features described herein can be used in the context of one or more AM parts such that the elements used to house the retention features (e.g., grooves, apertures, elastic elements, etc.) can advantageously be co-printed with the AM part, thereby removing a manufacturing step. The retention features also can be made with flatter profiles than existing solutions, making the overall structure smaller and less cumbersome to assemble.

Abstract: A node to panel interface structure for use in a transport structure such as a vehicle is disclosed. In an aspect, the node includes a base, first and second sides protruding from the base to form a recess for receiving a panel, ports for adhesive injection and/or vacuum generation, one or more adhesive regions disposed on a surface of each side adjacent the panel, and at least one channel coupled between the first and second ports and configured to fill the adhesive regions with an adhesive, the adhesive being cured to form a node-panel interface. The node may be additively manufactured. In an exemplary embodiment, the node may use sealant features for including sealants that border and define the adhesive regions, and that may hermetically seal the region before and after adhesive injection. In another embodiment, the node may include isolation features for including isolators for inhibiting galvanic corrosion.

Abstract: An additively manufactured node is disclosed. A node is an additively manufactured (AM) structure that includes a feature, e.g., a socket, a channel, etc., for accepting another structure, e.g., a tube, a panel, etc. The node can include a node surface of a receptacle extending into the node. The receptacle can receive a structure, and a seal interface on the node surface can seat a seal member between the node surface and the structure to create an adhesive region between the node and the structure, the adhesive region being bounded by the node surface, the structure, and the seal member. The node can also include two channels connecting an exterior surface of the node to the adhesive region. In this way, adhesive can be injected into the adhesive region between the node and the structure, and the adhesive can be contained by the seal member.

Abstract: A node may be additively manufactured. The node may include a first surface and a second surface, and the second surface may bound a recess of the node. A structure may be inserted into the recess. A sealing member extend away from the second surface and contact the structure, such that a sealed space may be created between the node and the structure. An adhesive may be applied in the sealed space to at least partially attach the structure to the node.

Abstract: Apparatus and methods for joining nodes to tubes with node to tube joints are presented herein. Joining techniques allow the connection of additively manufactured nodes to tubes. In an embodiment, at least one node may be joined to a tube and may be a part of a vehicle chassis. The node to tube joint connection incorporates adhesive bonding between the node to tube to realize the connection. Sealants may be used to provide sealed regions for adhesive injection, which are housed in sealing interfaces co-printed with the additively manufactured nodes. Additionally, seals may act as isolators and reduce galvanic corrosion.