A spherical body inspection apparatus including a support arrangement realized to support a spherical body during an inspection procedure; a probe arrangement comprising a plurality of ultrasonic testing probes arranged about the spherical body such that the ultrasonic testing probes target a common test point at the surface of the spherical body; and a displacer for effecting at least one relative rotational displacement between the spherical body and the probe arrangement. Also described is a method of inspecting a spherical body.

An ultrasonic flaw detection method and device identifies echoes appearing in flaw detection images. By selecting and controlling combinations of transmitting elements and receiving elements, plural waveform signals c are recorded. For each position in an inspection object, intensities of plural waveform signals are extracted based on the propagation time of ultrasonic waves and are totalized. A flaw detection image showing distribution of totalized intensities is generated. By selectively using at least three sound velocities for calculating propagation time of ultrasonic waves, at least three flaw detection images are generated. The areas of at least three echoes respectively appearing in the flaw detection images are calculated and the echo area which is the smallest is identified according to whether or not the flaw detection image showing the echo is one generated using one of a longitudinal sound velocity, a transverse sound velocity and a medium sound velocity.

The invention relates in particular to a method for determining physical, chemical, and/or biological properties of a medium (M) located in the interior (30) of a waveguide (3) using at least one acoustic wave which has propagated at least partly through the medium (M). According to the invention, a first wall section (31a) and a second wall section (31b) of the waveguide (3) are connected together via a connection piece (31c) such that a second surface wave (OW2) propagates to the first wall section (31a) at least partly via the connection piece (31c). One of the wall sections (31a, 31b) and/or the connection piece (31c) is provided with at least one reflective element (4) on which at least one pert of a: least one first surface wave (OW1) that is excited on the first wall section (31a) by incurs of a transmitter (SE) is reflected ss a third surface wave (OW1). A receiver (SE) is used to receive second and third surface waves (OW2, OW1) on the first wall section (31a), and the second and third surface waves are used to determine physical, chemical, and/or biological properties of the medium (M).

A method for examining a sample (50) including the steps of exciting a propagating mechanical deformation (2) in the sample (50) using a fluidic oscillator (10), and determining a characteristic of the mechanical deformation (2).

It is provide a method for determining at least one of physical, chemical and biological properties of a medium with the aid of at least two transmitter-receiver pairs and on the basis of at least one first and one second acoustic wave. The first acoustic wave has propagated at least in part between a first transmitter-receiver pair through the medium and the second acoustic wave has propagated at least in part between a second transmitter-receiver pair through the medium, wherein the medium adjoins an inner lateral surface of an elongate conduction element that is arched transversely to its direction of longitudinal extent.

A fluid meter has a housing comprising a flow channel for fluid to be measured and at least one elongate module-receiving opening forming a passage from an outer surface of the housing to the flow channel. At least one fluid-measuring module, prefabricated separately, from the housing with a base section formed as a waveguide for surface acoustic waves, and at least one signal transformer to excite surface acoustic waves in the waveguide and/or receive surface acoustic waves from the waveguide is provided. When inserted into the module-receiving opening, the base section of the fluid-measuring module forms part of the flow channel inner wall and contacts fluid flowing through it. Surface acoustic waves emitted by the signal transformer can be coupled out of the waveguide and can propagate through the fluid in the flow channel as bulk acoustic waves and/or bulk acoustic waves can be coupled into the waveguide and received by the signal transformer.

It is provided an apparatus for determining at least one of physical, chemical and biological properties of a medium, comprising an acoustic waveguide, which has a conduction element with an inner side that faces the medium and an outer side that lies opposite this inner side. The inner side facing the medium is curved in concave fashion and the outer side is curved in convex fashion and the waveguide with the conduction element curved in that way is configured such that a second surface wave coupling-in at the concave inner side propagates along a propagation direction to the receiver. At least one damping element lies downstream of the receiver in the propagation direction of the second surface wave, said damping element being arranged and configured to prevent surface waves propagating counter to the propagation direction of the at least one second surface wave from reaching the receiver.

A method for testing material joints or material compounds includes: (a) providing an arrangement to be tested consisting of at least two components, connected via a material joint, (b) excitation of acoustic waves in at least one component, in the provided arrangement to be tested, with laser pulses from a laser light source, (c) detecting ultrasound waves in a gaseous layer adjacent to the provided arrangement to be tested with a membrane-free optical microphone, (d) evaluating the ultrasound waves detected by determining an acoustic pressure variation of the ultrasound waves; and (e) evaluating the respective material joint based on the occurring mode conversion of a symmetrical mode with a first out-of-plane deflection into an asymmetrical mode with a second out-of-plane deflection, and/or based on acoustic standing waves at resonant frequencies in the material joint.

The invention relates in particular to a method for determining physical, chemical, and/or biological properties of a medium (M) located in the interior (30) of a waveguide (3) using at least one acoustic wave which has propagated at least partly through the medium (M). According to the invention, a first wall section (31a) and a second wall section (31b) of the waveguide (3) are connected together via a connection piece (31c) such that a second surface wave (OW2) propagates to the first wall section (31a) at least partly via the connection piece (31c). One of the wall sections (31a, 31b) and/or the connection piece (31c) is provided with at least one reflective element (4) on which at least one pert of a: least one first surface wave (OW1) that is excited on the first wall section (31a) by incurs of a transmitter (SE) is reflected ss a third surface wave (OW1). A receiver (SE) is used to receive second and third surface waves (OW2, OW1) on the first wall section (31a), and the second and third surface waves are used to determine physical, chemical, and/or biological properties of the medium (M).

It is provide a method for determining at least one of physical, chemical and biological properties of a medium with the aid of at least two transmitter-receiver pairs and on the basis of at least one first and one second acoustic wave. The first acoustic wave has propagated at least in part between a first transmitter-receiver pair through the medium and the second acoustic wave has propagated at least in part between a second transmitter-receiver pair through the medium, wherein the medium adjoins an inner lateral surface of an elongate conduction element that is arched transversely to its direction of longitudinal extent.