A method of bonding a second object to a first object includes: providing the first object having a thermoplastic liquefiable material in a solid state; providing the second object having a surface portion that has a coupling structure with an undercut, so that the second object is capable of making a positive-fit connection with the first object; pressing the second object against the first object with a tool that is in physical contact with a coupling-in structure of the second object while mechanical vibrations are coupled into the tool; continuing to press and couple vibrations into the tool until a flow portion of the thermoplastic material of the first object is liquefied and flows into the coupling structures of the second object; and letting the thermoplastic material re-solidify to yield a positive-fit connection between the first and second objects by the re-solidified flow portion interpenetrating the coupling structures.

A method of joining workpieces includes the steps of bringing a first workpiece and a second workpiece together, induction heating a susceptor material, and pressing the workpieces together. Each workpiece may include a thermoplastic material, and the workpieces are brought together at a joint interface so that a protrusion of the first workpiece is aligned with a receptacle of the second workpiece. The susceptor material is in contact with the thermoplastic material of the first workpiece during heating such that the thermoplastic material of the first workpiece softens. The step of pressing is performed while the thermoplastic material of the first workpiece is softened, thereby reshaping the first workpiece where the susceptor material is in contact with the thermoplastic material of the first workpiece. The protrusion is deformed to form an interlock with the receptacle at the joint interface.

The present disclosure can provide for an ultrasonic welding method for a pair of workpieces. The method can include first pressing an ultrasonic welding stack against a first workpiece in the pair so that the first workpiece comes into contact with a second workpiece in the pair. The method can then provide for initiating a weld phase by outputting energy from the ultrasonic welding stack to the first workpiece. The method can provide for monitoring, with at least one sensor, a sensed parameter. The sensed parameter can be, for example, weld force and/or weld force rate of change. The method can provide for determining whether the sensed parameter has reached a predetermined level. Based on determining that the sensed parameter has reached the predetermined level, the method can provide for ending the weld phase.

A case includes a first member and a second member configured in such a way that a closed space is formed between the first and second members in a state where the first and second members abut against each other. The first member includes a shaft portion extending toward the second member. The second member includes a shaft support portion including a circumferential wall portion that surrounds one end portion of the shaft portion. The shaft portion includes an enlarged-diameter portion that is the one end portion melted in such a way as to be enlarged in diameter.

A disclosed screening apparatus includes a subgrid, and a screen element attached to the subgrid via laser welding at a plurality of attachment positions such that, under vibrational excitation, the screen element has a pre-determined profile of vibrational motion relative to the subgrid. The screen element may be attached at a maximal number of attachment locations to the subgrid to minimize relative motion of the screen element and the subgrid under vibrational excitation, or the screen element may be attached a sub-set of the maximal number of attachment locations to allow vibrational motion of the screen element relative to the subgrid. A disclosed method may include attaching a plurality of screen elements to a respective plurality of subgrids, attaching the plurality of subgrids to one another to form a screening pre-assembly, and cutting edges of the screening pre-assembly to form the screen assembly having a perimeter with a pre-determined shape.

The present disclosure relates to a template and a related method for the application of inserts in the form of letters, numbers or symbols on leather, fabrics, cloth, or similar laminar products to customize them. The centering template comprises a main support body (101) having a centering system (106) to allow an engagement of the template (100) in pre-fixed position to a base (3a) of a press (3); and a centering element (102) configured to receive in pre-fixed position at least a laminar portion (103) of an accessory (104). The centering element (102) has a through seat (105) for the inserts (11) and it is movable with respect to the main support body (101) between an extracted resting position in which an upper surface (102a) of the centering element (102) is moved away from the main support body (101) and a working position in which the upper surface (102a) of the centering element (102) is approached to the main support body (101). The template allows the correct positioning of the characters on the accessory both in terms of alignment, and in terms of distance from the edges and from the other inserts of the accessory (handles, buckles, etc. . . . ) and regardless of the shape assumed by the laminar portion itself.

A method of bonding a second object to a first object includes: providing the first object having a thermoplastic liquefiable material in a solid state; providing the second object having a surface portion that has a coupling structure with an undercut, so that the second object is capable of making a positive-fit connection with the first object; pressing the second object against the first object with a tool that is in physical contact with a coupling-in structure of the second object while mechanical vibrations are coupled into the tool; continuing to press and couple vibrations into the tool until a flow portion of the thermoplastic material of the first object is liquefied and flows into the coupling structures of the second object; and letting the thermoplastic material re-solidify to yield a positive-fit connection between the first and second objects by the re-solidified flow portion interpenetrating the coupling structures.

A microfluidic flow cell for carrying out an analysis, having a substrate of synthetic material, which has cavities for the formation of channel structures and chambers, wherein the cavities are closed on one side of the substrate by a film adhesively bonded or welded to the substrate, and having a housing component that is produced with a hard and a soft component, which, on the side of the substrate facing away from the film, is connected to the substrate, completing functional sections respectively fulfilling the function of the flow cell. The housing component is formed as a multifunctional part completing more than two functional sections.

This disclosure details exemplary battery pack designs for use in electrified vehicles or other electrified components. An exemplary battery pack may include a heat exchanger plate assembly having a metallic plate and a polymeric plate that are joined together to establish a coolant circuit therebetween. The metallic plate or the polymeric plate may include a protrusion that extends through an opening of the other of the metallic plate or the polymeric plate. The protrusion may either be crimped or heat staked to a surface surrounding the opening in order to join together the metallic plate and the polymeric plate of the heat exchanger plate assembly.

A novel spring-loaded device utilizes a linear or rotary measuring sensor to measure distance and control heat using a PID loop or other type of control loop feedback program. The power of the heating element is controlled by a program, which takes distance from the target into consideration when determining output power. For example, if the target distance is 10 mm away the algorithm will apply 100% power until reaching 9 mm, at which point it will lower power to 90%. When the distance is 5 mm from the target, the power level will be 50%, and so on and so forth. The closed loop nature of the system will reduce power automatically using pulse width modulation (PWM) of the input power. This will allow modulation of the power to the heating element on the fly.