A method for connecting at least two structural parts of an orthopedic component, wherein the structural parts are retained in an orienting device while oriented in relation to each other, and an intermediate space thus being formed between the structural parts. The orienting device and the structural parts together form a cavity, which has a flow connection to at least one feed connection, via which an adhesive for adhesively bonding the structural parts is introduced into the cavity.

An intentionally activated frangible bonding system comprises a frangible adhesive, adhesive primer, composite material matrix, and/or the like, having a polydispersion of at least one additive spread throughout the frangible bonding material. The additive degrades a bond provided by the frangible bonding material, upon application of a specific energy to the frangible bonding material. An energy emitter is configured to selectively direct the specific energy toward a structure or assembly comprising components bonded by the frangible bonding material to degrade the frangible bonding material bonding the components for disassembly.

Methods for forming rotor blades, rotor blade mold assemblies, and cores for rotor blade mold assemblies are disclosed. A method includes providing a first shell substrate on a first mold, providing a generally hollow core on the first shell substrate, providing a second shell substrate on the generally hollow core, and providing a second mold on the second shell substrate. The method further includes flowing a resin into a mold interior defined between the first mold and the second mold.

A block assembly for connecting a first section and a second section of a load bearing assembly includes a male fitting and a female fitting. The male fitting includes a male fitting body and a projection extending from the male fitting body. The female fitting includes a female fitting body and defines a fitting cavity extending within an interior of the female fitting body. The male fitting couples with the female fitting by inserting the male fitting body within the fitting cavity and moving the male fitting body toward a base of the female fitting. The projection on the male fitting interacts with an interlocking joint on the female fitting to resist detachment of the male fitting with respect to the female fitting.

A system and method are provided for manufacturing a plastic pallet having a plurality of runner assemblies with embedded support structures. Each runner assembly may include a top runner board, a bottom runner board, and a plurality of support structures embedded into the top and bottom runner boards. The pallet may be manufactured using heat to at least partially penetrate and soften the runner boards, to soften the support structures, and to weld the support structures to the runner boards in an embedded manner.

An impeller of a centrifugal fan includes multiple blades arranged annularly around a rotational axis, a main plate, a shroud, main plate-side welded portions between main plate-side blade axial ends of the blades and the main plate, and shroud-side welded portions between shroud-side blade axial ends of the blades and the shroud. The main plate is arranged opposite to main plate-side blade axial ends. The shroud is arranged opposite to shroud-side blade axial ends. The main plate-side welded portions have main plate-side welding holes that are recesses extending through the main plate to portions of the main plate-side blade axial ends. The shroud-side welded portions have shroud-side welding holes that are recesses extending through the shroud to portions of the shroud-side blade axial ends.

A system (100), for manufacturing a rotor blade (112), comprises a first tooling (170), positioned at a factory location (114) and configured to assemble a first blade module (116), comprising a first-module skin (118) and a first-module spar (120), each comprising a first thermoplastic polymer (122) and a first reinforcement material (124). The system (100) comprises a second tooling (172), configured to assemble a second blade module (126), comprising a second-module skin (128) and a second-module spar (130), each comprising a second thermoplastic polymer (132) and a second reinforcement material (134). The system (100) comprises a first support (160), positioned at a field location (140) and configured to receive the first blade module (116), and a second support (162), positioned at the field location (140) and configured to receive the second blade module (126). The system (100) comprises a spar welding assembly (174), positioned at the field location (140) and configured to join the first-module spar (120) with the second-module spar (130), and a skin welding assembly (176), positioned at the field location (140) and configured to join the first-module skin (118) with the second-module skin (128).

A microfluidic device comprises a first substrate (102) made of a first polymer material and a second substrate (104) made of a second polymer material, the first (102) and second (104) substrates having respective bonding surfaces (23, 41), at least one of the bonding surfaces (41) having channel formations (14) so that, when the bonding surfaces (23, 41) are bonded by surface deformation to one another, the bonded first and second substrates (102, 104) and the channel formations (14) form at least part of a microfluidic channel network comprising a plurality of microfluidic channels, wherein one or more indicator pits (11), separate to the channel formations (14) defining the microfluidic channel network, are formed in at least one of the bonding surfaces (23, 41), so that surface deformation caused by the bonding process causes a change of configuration of the one or more indicator pits (11).

Disclosed herein are methods, devices, and systems for manufacturing wind turbine blades which in some instances require using new blade joint designs. The blade joint designs described herein may allow for contact in places where welds will be made, which allows for existing manufacturing tolerances to be used while still enabling the use of thermal welding for wind turbine blades.

A method of producing a golf ball applies ultrasonic welding on two half shells to form at least one intermediate layer, at least one cover layer, or at least one intermediate layer and at least one cover layer. The ultrasonic welding may include pressing the two half shells together, delivering a high power electrical signal to a welding stack, and converting the high power electrical signal at the welding stack to ultrasonic energy. The converting may include converting the high power electrical signal into a mechanical vibration, modifying an amplitude of the mechanical vibration to generate a modified mechanical vibration, and applying the modified mechanical vibration to an interface of the two half shells to weld them together ultrasonically. Aspects also relate to golf balls, or one or more layers thereof, made using ultrasonic welding.