Methods for measuring a resonance frequency of a tool set in ultrasonic vibration during the machining of a workpiece, involving radiating a working signal with a working frequency into a tool holder comprising a tool by a generator to produce the ultrasonic vibration of the tool; after the start of the machining of the workpiece, radiating a test signal with a test frequency varying by the working frequency and a lower power than the working signal power into the tool holder by the generator; generating a sensor signal from the ultrasonic vibration of the tool by a sensor apparatus arranged in the tool holder; reading out the sensor signal by a read-out apparatus; splitting the sensor signal into a frequency spectrum involving a main frequency and an auxiliary frequency by an analytical apparatus; determining the main frequency from the working frequency and the auxiliary frequency from the resonance frequency.

In an ultrasound cutting device comprising an ultrasound transducer connected to a generator and provided with a sound conductor which is connected to a cutting blade and extends along a line which deviates from a straight line, the generator includes means for running the ultrasound waves in a controlled manner through a predetermined frequency range.

To provide a manufacturing method for a composite material, a manufacturing apparatus for a composite material, a preform, and a composite material, capable of molding a high quality composite material having a little constraint in the shape by improving moldability while suppressing a deviation of the arrangement of the reinforced fiber during preforming. A manufacturing method for a composite material 400 provided with a reinforcement 510 and resin 600 infused into the reinforcement, includes: an apply process (step S12) for applying an adhesive to the sheet-shaped reinforcement having first and second regions 511 and 512 such that a content density of the adhesive 520 of the second region is lower than that of the first region; and a preforming process (step S17) for preforming the reinforcement in a three-dimensional shape to form a preform such that the second region has a curvature larger than that of the first region.

A movement controller controls a feed mechanism to move a vibration device relative to a workpiece. A vibration controller controls vibration of piezoelectric elements of the vibration device. The vibration controller acquires a status value indicating a vibration control status and detects contact between a cutting tool and the workpiece or the like based on a change in the status value. The vibration controller acquires at least one among energy consumption required for the vibration and a resonance frequency as the status value. The vibration controller determines a relative positional relationship between the cutting tool and a rotation center of the workpiece based on coordinate values of at least two contact positions.

The invention relates to a method for cutting material to be cut, which is preferably realized as a rod-shaped element, comprising a receiving device for fixedly receiving the material to be cut in such a manner that a part to be separated from the material to be cut protrudes over an element edge of the receiving device realized as a counter knife edge (42), and comprising a knife unit having a knife (24), which is movable with respect to the receiving device and which moves a knife edge (25) past the counter knife edge (42) in a cutting movement for executing a separating cut, the welding material being subjected to ultrasound for executing oscillations during the cutting movement.

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 multifunctional shaft apparatus includes a shaft base, a spindle, a tool holder, an ultrasonic vibration assembly, a laser light source and a mirror assembly. The spindle is disposed in the shaft base. The spindle has a laser channel extending along the spindle. The tool holder is disposed on the spindle. The tool holder has a hollow passage, an inner space and a recessed portion. The hollow passage is communicated with the laser channel. An inner wall of the hollow passage has at least one through hole communicated with the inner space, and the recessed portion is disposed on a bottom surface of the tool holder. The bottom surface has a light outlet. The ultrasonic vibration assembly includes a vibration member disposed in the recessed portion. The mirror assembly is disposed in the tool holder and is configured to reflect the laser light beam generated by the laser light source.

A notching apparatus for notching an object comprises a movable notching head including two or more profiled slots, shaped and sized to receive a portion of the object, a notching tool coupled to the notching head for cutting a notch in the object when received within one of the profiled slots, a notching actuator connected to the notching tool for moving the tool relative to the head, and a multi-axis positioning device for positioning the notching head relative to the object to be notched so as to align one of the two or more profiled slots with the object to be notched.

A cutting guide device for ultrasonic cutting of workpieces is provided. The cutting guide device includes a cutting edge with a cutting edge longitudinal axis held in the cutting guide device, an ultrasound generator which oscillates the cutting edge, a control unit which controls movement of the cutting edge on a cutting path, and a first force measuring device which measures an actual lateral force on the cutting edge transverse to the cutting edge longitudinal axis and transverse to the cutting direction. The first force measuring device sends actual lateral force measurement values to the control unit, which changes at least one cutting parameter based on the measured actual lateral force. A method for using the ultrasonic cutting device is also provided.

An ultrasonic cutting machine including a support structure, a positioning device moveable relative to the support structure, a cutting blade connected to the positioning device and a blade cleaning system positioned proximate the support structure, the blade cleaning system including a basin defining an internal volume and an opening into the internal volume, a solvent positioned in the internal volume, a cleaning surface positioned in the internal volume, wherein the cleaning surface is at least partially submerged in the solvent, and a lid positioned over the opening, wherein the lid is automatically displaced from the opening when the cutting blade approximates the basin.