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. In another aspect, adhesive may be filled serially on the adhesive regions on the first side and then on the adhesive regions on the second side. Adhesive may alternatively may be filled in parallel, or concurrently, on the adhesive regions of both sides.

A coupling system comprises a receiving component, an opening in the receiving component defined by a receiving wall and a mating component, configured to be placed into the opening in the receiving component and comprising a mating wall. A plurality of spaced receiving protrusions extends radially from one of the receiving wall or the mating wall, and are located serially to define a retaining groove. A locating rib is formed on, and extends about, the other of the receiving wall or the mating wall such that the mating component is pressed into the receiving component until the locating rib contacts the receiving protrusions. As additional insertion force is exerted upon the mating component the receiving protrusions yield in a radial direction, allowing the locating rib to enter the retaining groove for retention of the mating component relative to the receiving component.

A coupling system comprises a receiving component, an opening in the receiving component defined by a receiving wall and a mating component, configured to be placed into the opening in the receiving component and comprising a mating wall. A plurality of spaced receiving protrusions extends radially from one of the receiving wall or the mating wall, and are located serially to define a retaining groove. A locating rib is formed on, and extends about, the other of the receiving wall or the mating wall such that the mating component is pressed into the receiving component until the locating rib contacts the receiving protrusions. As additional insertion force is exerted upon the mating component the receiving protrusions yield in a radial direction, allowing the locating rib to enter the retaining groove for retention of the mating component relative to the receiving component.

An adhesive patch and method of use thereof for forming a plurality of stackable items into a vertically stacked load are described. The method may include delivering an aligned stack of items positioned on a pallet for eventual transportation while minimizing the misalignment of the stackable items.

A joint structure according to an embodiment of the present invention is provided with: a first member that is made of a metal material and has a plurality of holes having an opening diameter of 30-100 μm formed in a surface thereof; a third member that is made of a metal material the same as or different from that of the first member, or a thermoplastic resin, and that has a plurality of independent holes having an opening diameter of 30-100 μm formed in a surface thereof; and a second member that is made of a curable resin and joins the surface of the first member in which the holes are formed and the surface of the third member in which the holes are formed.

Devices and methods for attaching objects to living trees. Various forms of the devices employ a flexible member and mounting member that are configured to be looped and secured around a tree portion at a beginning of a predetermined time period. The mounting member and flexible member are configured to slide relative to each other to accommodate growth of the tree portion such that the device remains secured to the tree portion for at least the duration of the predetermined period of time without the need for human intervention. In other embodiments, the mounting member is integrally formed with the object or no mounting member is employed.

A component including at least one joint, at which a joining connection to a further component is to be formed later, is provided. A joining element having a holding section is pressed into the component, and the joining element also has a functional section, by way of which at least one further function can be implemented. The holding section of the joining element is arranged in a passage hole, and the passage hole is widened in at least one edge region by an embossing. The holding section of the joining element is pressed into the passage hole and is connected to the hole wall in a force-fitting and/or form-fitting manner and engages in the embossing. A component combination of at least two components which includes such a component and a method for producing the component and the component combination are also provided.

An adhesive and release liner application system and method. A bottom table is slidable with respect to a frame and a middle table is slidable with respect to the bottom table. An elevator drive subsystem between a top table and the middle table is configured to adjust the elevation of the top table relative to the middle table. An adhesive head, connected to an adhesive supply subsystem, a release liner applicator, a release liner cutter, and a staple gun are mounted to the top table for applying the adhesive to a surface of a structural member positioned adjacent the top table, for applying a release liner over the adhesive on the surface, for inserting at least one staple through the release liner and into the surface, and for cutting the release liner.

In a method for producing stacks of laminations, in which at least one adhesive is applied onto annular laminations with at least one application head and laminations are stacked into a stack of laminations, the lamination is rotated about its axis in the application area of the application head and/or the application head is moved about the axis of the lamination in order to apply the adhesive onto the lamination. A system for carrying out the method features at least one punching tool, with which laminations are punched out of a sheet metal material, wherein at least one station for cleaning and/or for activating and/or for applying an adhesive onto the laminations is arranged downstream of the punching tool.

A multi-material assembly is provided, as well as methods of making a multi-material assembly. The multi-material assembly includes a first coated structural component and a second structural component. The first coated structural component includes a first uncoated portion, and an adhesive is positioned between the second structural component and the first uncoated portion that secures the first coated structural component to the second structural component.