A method for producing an axially movable connection between two tubular components with a plastic as a sliding material therebetween may involve providing the components to be joined where either at least one of the two components has a plastic coating or a plastic sleeve is provided between the components, joining the components to form a unit via a pressing force in an axial direction, clamping the unit in a device in which the components can be clamped and subjected to a displacement force in the axial direction, pressing a sonotrode against an outer of the two components, injecting an ultrasound signal into the sonotrode at a frequency close to the resonance frequency of one of the components, and moving the tubular components back and forth in the axial direction until the displacement force or the displacement velocity reaches a target, and ending the ultrasound signal.

An ultrasonic systems and methods for sealing complex interfaces or for metal forming. Complex interfaces, such as a Gable top, have multiple and a variety of layers across the interface, or an oval or round spout having a complex geometry. An example system includes two ultrasonic horns arranged opposite a gap between which the interface is provided. The frequency and phase of the ultrasonic energy are synchronized as the energy is applied simultaneously while the interface is pressed between a jaw and the energy is applied to both sides of the interface. Another example system includes two ultrasonic transducers synchronized in frequency and phase and used to vibrate a horn mechanically to facilitate a sealing or welding interface or to assist in a metal-forming process.

A method of altering a portion of a substrate may include providing a first device and a second device with a nip therebetween. The second device may comprise a stationary or rotating source of vibration energy. When conveyed through the nip, the substrate may be exposed to the vibration energy and the portion thereof may be altered. Thermal energy may be applied to the portion of the substrate upstream of the nip to raise a temperature of the portion of the substrate to a temperature below a melting temperature thereof. A substrate spreader may contact the substrate upstream of the nip to mitigate fold over or wrinkles in the substrate. When the first device is a rotating anvil and the second device comprises a rotating source of vibration energy, the surface velocities thereof may be variable and may be the same or different.

A method of controlling an inductive heating circuit, having a varying load, to seal a packaging material is provided. The method comprises generating AC power of at least two frequencies on at least one inductor in the inductive heating circuit; determining of the resulting phase shift in the inductive heating circuit from the current generated at the at least two frequencies; determining the impedance of the inductive heating circuit for each of the at least two frequencies; determining a load characteristics of the inductive heating circuit based on the relationship between the determined impedance and the determined phase shift; determining an impedance operating range; and selecting an AC output frequency for an induction power generator based on the load characteristics which results in the least amount of phase shift from a set ideal value and which is associated with an impedance that is within the impedance operating range.

A method of controlling an inductive heating circuit, having a varying load, to seal a packaging material is provided. The method comprises generating AC power of at least two frequencies on at least one inductor in the inductive heating circuit; determining the resulting phase shift in the inductive heating circuit from the current generated at the at least two frequencies; determining the impedance of the inductive heating circuit for each of the at least two frequencies; determining a load characteristics of the inductive heating circuit based on the relationship between the determined impedance and the determined phase shift; determining an impedance operating range; and selecting an AC output frequency for an induction power generator based on the load characteristics which results in the least amount of phase shift from a set ideal value and which is associated with an impedance that is within the impedance operating range.

An ultrasonic system and method for sealing a complex interface, such as a Gable top, having multiple and a variety of layers across the interface, or an oval or round spout having a complex geometry. The system includes two ultrasonic horns arranged opposite a gap between which the interface is provided. The frequency and phase of the ultrasonic energy are synchronized as the energy is applied simultaneously while the interface is pressed between a jaw and the energy is applied to both sides of the interface. Only one application of the frequency- and phase-synchronized ultrasonic energy is required to hermetically seal all the layers of the interface together.

The present invention concerns an ultrasonic vibration unit having a converter (1) for converting an electric ac voltage into a mechanical ultrasonic vibration and a sonotrode which is vibrationally coupled to the converter (1), wherein the sonotrode and the converter (1) are matched to each other in such a way that the ultrasonic vibration unit can vibrate with a natural frequency f, in which a standing longitudinal wave having at least one vibration node and at least two vibration antinodes is formed within the ultrasonic vibration unit. To provide an ultrasonic vibration unit in which the parasitic vibrations which usually occur in operation with a working frequency are slight or do not occur, wherein at the same time the actual working frequency is not attenuated, it is proposed according to the invention that there is provided a damp vibration absorber unit (2) connected to the ultrasonic vibration unit by way of a coupling element (3), wherein the coupling element (3) is connected to the ultrasonic vibration unit at a vibration node, wherein the vibration absorber unit (2) is connected to a damping element (4) which is so adapted that it damps a vibration of the vibration absorber unit (2).

A method for producing an axially movable connection between two tubular components with a plastic as a sliding material therebetween may involve providing the components to be joined where either at least one of the two components has a plastic coating or a plastic sleeve is provided between the components, joining the components to form a unit via a pressing force in an axial direction, clamping the unit in a device in which the components can be clamped and subjected to a displacement force in the axial direction, pressing a sonotrode against an outer of the two components, injecting an ultrasound signal into the sonotrode at a frequency close to the resonance frequency of one of the components, and moving the tubular components back and forth in the axial direction until the displacement force or the displacement velocity reaches a target, and ending the ultrasound signal.

An anvil system for use in an ultrasonic bonder includes an anvil assembly including an anvil bar having an anvil aperture in at least one anvil bar longitudinal end, the anvil aperture having an anvil aperture inner surface, a shaft separate from the anvil bar and partially disposed in the anvil aperture, the shaft having a circumferential surface and extending outwardly beyond the anvil bar longitudinal end, and a first elastomeric shaft O-ring disposed on the shaft between the shaft circumferential surface and the anvil aperture inner surface; a mounting bracket with a mounting bracket hole having a hole surface; a bushing disposed in the mounting bracket hole and sized to accommodate an end of the shaft, the bushing having a bushing inner surface; and a second elastomeric shaft O-ring disposed on the shaft between the shaft circumferential surface and the bushing inner surface.

A system to re-configure an input material into an output material includes an input material feeder reconfigurable to accept and feed an input material, an output material spooler, the input material feeder re-configurable relative to the material cutter to cut the input material at a re-configurable cut angle to produce a first intermediate cut section of material, a positioning and alignment system to position and align a leading edge of the first intermediate cut section of material with a trailing edge of a second intermediate cut section of material, a welder having a configurable position to weld the first intermediate cut section of material to the second intermediate cut section of material, and a control system comprising logic to set at least intensity of the welder, a contact pressure of the welder, temperature of the weld-table surface, and a tension applied by the output material spooler.