The present invention provides an ultrasonic washer that radiates ultrasonic waves from a plurality of vibration surfaces, radiates ultrasonic waves at the same phase, effectively generates cavitation around a nozzle through ultrasonic vibration, and has a high washing effect. The ultrasonic washer of the present invention is characterized by having: a washing tank in which is washed a nozzle that suctions a sample or reagent; and an ultrasonic vibrator having a piezoelectric element sandwiched between a front mass and a back mass, wherein a diaphragm between opposing upper and lower plates is formed at a leading end of the front mass installed at a leading end of the ultrasonic vibrator, and the nozzle is ultrasonically washed in a region between the upper plate and the lower plate

A vibration device includes a cylindrical body including a cavity, a first opening end surface, and a second opening end surface, a light-transmissive cover directly or indirectly bonded to the first opening end surface of the cylindrical body so as to cover the cavity of the cylindrical body, a piezoelectric body directly or indirectly bonded to the cylindrical body, and a buffer layer provided between at least one of the cylindrical body and the piezoelectric body, and the cylindrical body and the light-transmissive cover. The buffer layer includes an inner end portion on an inner side portion in a direction orthogonal or substantially orthogonal to the axial direction and an outer end portion on an outer side portion in a direction orthogonal or substantially orthogonal to the axial direction. A thickness of the inner end portion is larger than a thickness of the outer end portion.

An ultrasonic dry coupled wheel probe with radial transducers emit ultrasound in substantially all radial directions relative to a longitudinal axis. The probe does not require normalization and is efficient in directing ultrasound to a surface being inspected. The probe has a wheel composed of rubber or other materials for acoustically dry coupling the transducer to the surface. A first transducer is composed of a piezoelectric material so that the transducer receives an electrical signal, vibrates, and generates and transmits sound, such as ultrasound. Similarly, a second transducer receives sound such as ultrasound, vibrates, and generates a corresponding electrical signal. The transducer arrangement both transmits ultrasound to the surface and receives the reflection of the ultrasound from the surface. An acoustic barrier separates the transmitting component from the receiving component. The transducer has annular electroplates adjacent to the piezoelectric material. The two transducers can comprise a single, integrated transducer module.

An apparatus includes a lens, a transducer and a driver, where the lens has a first side, a second side, and a lens radius, and the transducer has a transducer outer radius. The transducer is coupled to the first side of the lens, and the transducer outer radius is less than the lens radius. The driver has output terminals coupled to the transducer and is configured to provide an oscillating drive signal at a non-zero frequency to vibrate the lens. An o-ring is positioned between a clamp and the second side of the lens, where the o-ring has a nominal radius that is less than or equal to a nominal radius of the transducer.

A vibration device includes a cylindrical body including a cavity, a first opening end surface, and a second opening end surface, a light-transmissive cover directly or indirectly bonded to the first opening end surface of the cylindrical body so as to cover the cavity of the cylindrical body, a piezoelectric body directly or indirectly bonded to the cylindrical body, and a buffer layer provided between at least one of the cylindrical body and the piezoelectric body, and the cylindrical body and the light-transmissive cover. The buffer layer includes an inner end portion on an inner side portion in a direction orthogonal or substantially orthogonal to the axial direction and an outer end portion on an outer side portion in a direction orthogonal or substantially orthogonal to the axial direction. A thickness of the inner end portion is larger than a thickness of the outer end portion.

A vibration apparatus includes a vibrating body that has a tubular shape and includes first and second opening end portions, an outside surface, and an inside surface, a light transmissive body connected to the second opening end portion of the vibrating body, and a piezoelectric vibrator provided in the vibrating body. The vibrating body includes a flange portion extending from the outside surface of the vibrating body toward an outside. The vibration apparatus further includes a driving circuit that vibrates a connection body of the light transmissive body and the vibrating body in a vibration mode of light transmissive body vibration or a vibration mode of flange portion vibration and that alternately switches between the vibration mode of the light transmissive body vibration and the vibration mode of the flange portion vibration.

A communication system may communicate by backscattered acoustic signals that propagate through a liquid or solid. In this system, one or more transmitters may transmit acoustic signals that travel to, and are reflected by, an acoustic backscatter node. The backscatter node may modulate the amplitude and/or phase of the reflected acoustic signals, by varying the acoustic reflectance of a piezoelectric transducer onboard the node. The modulated signals that reflect from the backscatter node may travel to a microphone and may be decoded. The backscatter node may include sensors, and the uplink signals may encode sensor readings. The backscatter node may harvest energy from the downlink acoustic signals, enabling the node and the sensors to be battery-free. Multiple backscatter nodes may communicate concurrently at different acoustic frequencies. To achieve this, each node may have a matching circuit with a different resonant frequency.

Systems and methods for monitoring organisms within an aquatic environment are described. According to one aspect, an injectable acoustic transmission device includes a body configured to be injected inside of an organism, a transducer within the body and configured to convert a plurality of electrical signals into a plurality of data transmissions which are transmitted externally of the body and the organism, a plurality of circuit components within the body and configured to use electrical energy from a power source to generate the electrical signals which are provided to the transducer, and wherein the transducer defines an internal volume and at least one of the circuit components is provided within the internal volume of the transducer.

The objective of this invention is to provide an ultrasonic-wave transmitter/receiver with a fastening member that enables the case of such transmitter/receiver to be fastened reliably without impairing the usability of such transmitter/receiver during normal use. The ultrasonic-wave transmitter/receiver 10 comprises an ultrasonic transducer that transmits and receives ultrasonic waves; a case 50 that houses the ultrasonic transducer; and a cable 40 that suspends the case 50. The case 50 is of a hanging-bell shape comprising a lower-half part 51 having a bottom surface 52 and an outer-peripheral surface 53; and an upper-half part 61 having a structure of which the outer diameter gradually decreases toward the upper end. At least the lower-half part 51 of the case 50 is made of an elastic body. The groove 57 extending in the circumferential direction of the lower-half part 51 is formed on the outer-peripheral surface 53 of the lower-half part 51.

Pressure vessels that operate at elevated temperatures and pressures (e.g., 600° F./316° C., 20000 psig), and ultrasonic transducers and signal connectors for use therein, are described. The pressure vessels include a housing defining a cavity. The housing includes a cylindrical body with plugs positioned within openings of the cylindrical body. Each plug has a recess extending from an external surface to a location ultrasonically adjacent the cavity. The pressure vessels additionally include transducer assemblies positioned within respective plug recesses. Each transducer assembly includes a signal connector positioned within the recess adjacent the external surface, a transducer having a piezoceramic element positioned within the recess at the location ultrasonically adjacent the cavity, and a metallic interconnection spring interconnecting the transducer to the signal connector.