Abstract: The present invention provides an attachment for an ultrasonic-wave transmitter/receiver that can be used by changing directivity characteristics according to the situation, even if there is only one ultrasonic-wave transmitter/receiver. The attachment 60 to be attached to the ultrasonic-wave transmitter/receiver 10 comprises an acoustic lens 81, a holding member 61, and horizontal maintenance means 71. The acoustic lens 81 has a flat surface 82 and a convex surface 83 located on the opposite side. The holding member 61 holds the acoustic lens 81 with the flat surface 82 facing upward as well as detachably holds the ultrasonic transducer 10, so as to acoustically connect the acoustic radiation surface 10a to the flat surface 82. The horizontality-maintaining means 71 horizontally maintains the ultrasonic-wave transmitter/receive 10 and the acoustic lens 81.

Abstract: An attachment for an ultrasonic transducer can be used for changing the directivity characteristics of ultrasonic waves irradiated from a radiation surface depending on the situation, even if there is only one ultrasonic-wave transmitter/receiver. The attachment is adapted to be attached to the ultrasonic transducer and comprises a holding member, a buoyant body, and a directivity-characteristic changing member. The holding member has a holding concave portion that detachably holds the ultrasonic-wave transmitter/receiver. The buoyant body is provided so as to surround the holding member from the outer peripheral side, and is made of a material whose specific gravity is less than that of water and maintains the ultrasonic-wave transmitter/receiver horizontally by the buoyancy acting on itself.

Abstract: The present invention provides an attachment for an ultrasonic-wave transmitter/receiver that can be used by changing directivity characteristics according to the situation, even if there is only one ultrasonic-wave transmitter/receiver. The attachment 60 to be attached to the ultrasonic-wave transmitter/receiver 10 comprises an acoustic lens 81, a holding member 61, and horizontal maintenance means 71. The acoustic lens 81 has a flat surface 82 and a convex surface 83 located on the opposite side. The holding member 61 holds the acoustic lens 81 with the flat surface 82 facing upward as well as detachably holds the ultrasonic transducer 10, so as to acoustically connect the acoustic radiation surface 10a to the flat surface 82. The horizontality-maintaining means 71 horizontally maintains the ultrasonic-wave transmitter/receive 10 and the acoustic lens 81.

Abstract: An ultrasonic transducer for a measuring instrument includes a housing container with a support plate and a piezoelectric element that is supported by the support plate and has a substantially circular shape. The piezoelectric element includes multiple substantially sector-shaped oscillation parts that are divided by multiple grooves that communicate with each other at the central part and extend radially. The piezoelectric element oscillates in the thickness direction A3 in the first frequency band and in the radial direction A4 in the second frequency band, which is lower than the first frequency band. The ultrasonic transducer is capable of expanding the frequency band suitable for transmitting and receiving ultrasound.

Abstract: An ultrasonic transducer for a measuring instrument includes a housing container with a support plate and a piezoelectric element that is supported by the support plate and has a substantially circular shape. The piezoelectric element includes multiple substantially sector-shaped oscillation parts that are divided by multiple grooves that communicate with each other at the central part and extend radially. The piezoelectric element oscillates in the thickness direction A3 in the first frequency band and in the radial direction A4 in the second frequency band, which is lower than the first frequency band. The ultrasonic transducer is capable of expanding the frequency band suitable for transmitting and receiving ultrasound.

Abstract: The objective of this invention is to provide an ultrasonic-wave transmitter/receiver fish-finder that stabilizes its balanced state while in water to transmit ultrasonic waves vertically downward, thus improving detection accuracy. The ultrasonic-wave transmitter/receiver 10 includes an ultrasonic transducer 21 that transmits and receives ultrasonic waves; a hanging-bell shaped case 50 that houses the ultrasonic transducer 21; and a cable 40 that suspends the case 50. A weight 81 is arranged above the ultrasonic transducer 21 provided at the bottom 54 of the case 50. In addition, the filler A1 is filled into the case 50 such that a cavity A2 is secured in the upper region of the case 50.

Abstract: The object of this invention is to provide an ultrasonic transducer for a measuring device capable of widening a frequency band suitable for transmitting and receiving ultrasonic waves while reducing the manufacturing cost. The ultrasonic transducer for a measuring device includes a substantially disc-shaped base material that serves too as an acoustic-matching layer and substantially disc-shaped piezoelectric element that is joined to the base material. The piezoelectric element is formed with grooves extending in the planar direction so that they do not cross one another, and the plurality of strip-shaped vibration units are arranged through the grooves. The length of the vibration unit becomes shorter as the distance from the center of the piezoelectric element increases. Then, the piezoelectric element vibrates in the thickness direction in the first-frequency band and vibrates in the radial direction in the second-frequency band, which is lower than the first-frequency band.

Abstract: The flasher-type multi-frequency fish finder includes a wideband ultrasonic transducer, a display-rotating disk, a motor and a control device. The plurality of display LEDs are composed of the first, second and third display LEDs. The control device has a signal-separating and obtaining part and a light-emission signal-producing part. The signal-separating and obtaining part separates the reflected signal and obtains the first reflected signal corresponding to the high frequency, the second reflected signal corresponding to the medium frequency, and the third reflected signal corresponding to the low frequency. The light-emission signal-producing part generates first, second and third light-emission signals based on the first, second and third reflection signals, respectively. The first, second and third annular-display regions are concentrically set on the display surface.

Abstract: The objective of this invention is to provide an ultrasonic-wave transmitter/receiver fish-finder that stabilizes its balanced state while in water to transmit ultrasonic waves vertically downward, thus improving detection accuracy. The ultrasonic-wave transmitter/receiver 10 includes an ultrasonic transducer 21 that transmits and receives ultrasonic waves; a hanging-bell shaped case 50 that houses the ultrasonic transducer 21; and a cable 40 that suspends the case 50. A weight 81 is arranged above the ultrasonic transducer 21 provided at the bottom 54 of the case 50. In addition, the filler A1 is filled into the case 50 such that a cavity A2 is secured in the upper region of the case 50.

Abstract: The object of this invention is to provide an ultrasonic transducer for a measuring device capable of widening a frequency band suitable for transmitting and receiving ultrasonic waves while reducing the manufacturing cost. The ultrasonic transducer for a measuring device includes a substantially disc-shaped base material that serves too as an acoustic-matching layer and substantially disc-shaped piezoelectric element that is joined to the base material. The piezoelectric element is formed with grooves extending in the planar direction so that they do not cross one another, and the plurality of strip-shaped vibration units are arranged through the grooves. The length of the vibration unit becomes shorter as the distance from the center of the piezoelectric element increases. Then, the piezoelectric element vibrates in the thickness direction in the first-frequency band and vibrates in the radial direction in the second-frequency band, which is lower than the first-frequency band.

Abstract: 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.

Abstract: An electromechanical transformation device for an ultrasonic flow meter comprises an alkaline niobate piezoelectric ceramic composition and a rigid body adhered onto the major surface of the ceramic composition. The ceramic composition is made of crystal structures such as orthorhombic crystals formed at the side where the temperature is lower than the orthorhombic-to-tetragonal phase transition temperature, tetragonal crystals formed at the side where temperature is higher that the orthorhombic-to-tetragonal phase transition temperature as well as at the side where the temperature is lower than the tetragonal-to-cubic phase transition temperature, and the cubic crystals formed at the side where the temperature is higher than the tetragonal-to-cubic phase temperature. Young's modulus of the rigid is 60 GPa or more. The volume percent of the ceramic composition existing within a range where the distance from the adhesion point of the piezoelectric ceramic composition and the rigid body is 40% or more.

Abstract: A sensor-clamp device for clamping a pipe of different outer-diameters promptly without having to do a time-consuming sensor-position adjustment includes a pair of ultrasonic-sensors incorporating an ultrasonic-transducer for sending and receiving ultrasonic-waves ‘So’ and further includes a supporting-plate on which is provided a sliding-mechanism. The pair of ultrasonic-sensors clamps the outer-wall of the pipe in which flows a fluid W1. Of the supporting-plate, the pair of ultrasonic-sensors used in irradiating the ultrasonic-waves ‘So’ obliquely to the pipe are offset in the axial-line direction of the pipe and firmly placed face to face. The sliding-mechanism slides one of the pair of ultrasonic-sensors obliquely with respect to the axial-line direction of the pipe, thus making the sliding-mechanism to clamp the pipe of various outer-diameters.

Abstract: This invention provides a sensor-clamp device for clamping a pipe 4 of different outer-diameters promptly without having to do a time-consuming sensor-position adjustment. The sensor-clamp device 2 comprises a pair of ultrasonic-sensors 11, 12 incorporating an ultrasonic-transducer 10 for sending and receiving ultrasonic-waves ‘So’ and comprises a supporting-plate 30 on which is provided a sliding-mechanism 33. The pair of ultrasonic-sensors 11, 12 clamps the outer-wall 5 of the pipe 4 in which flows a fluid W1. Of the supporting-plate 30, the pair of ultrasonic-sensors 11, 12 used in irradiating the ultrasonic-waves ‘So’ obliquely to the pipe 4 are offset in the axial-line direction of said pipe 4 and firmly placed face to face. The sliding-mechanism 33 slides one of the pair of ultrasonic-sensors 11 obliquely with respect to the axial-line direction of the pipe 4, thus making the sliding-mechanism 33 to clamp the pipe 4 of various outer-diameters.

Abstract: An electromechanical transformation device for an ultrasonic flow meter comprises an alkaline niobate piezoelectric ceramic composition and a rigid body adhered onto the major surface of the ceramic composition. The ceramic composition is made of crystal structures such as orthorhombic crystals formed at the side where the temperature is lower than the orthorhombic-to-tetragonal phase transition temperature, tetragonal crystals formed at the side where temperature is higher that the orthorhombic-to-tetragonal phase transition temperature as well as at the side where the temperature is lower than the tetragonal-to-cubic phase transition temperature, and the cubic crystals formed at the side where the temperature is higher than the tetragonal-to-cubic phase temperature. Young's modulus of the rigid is 60 GPa or more. THe volume percent of the ceramic composition existing within a range where the distance from the adhesion point of the piezoelectric ceramic composition and the rigid body is 40% or more.

Abstract: A piezoceramic composition comprises, as the main phase, a crystalline phase of a perovskite structure signified as formula ABO3, with Element A consisting of one or more elements selected from among K (potassium), Na (sodium) and Li (lithium) and with Element B consisting of one or more elements selected from among Nb (niobium), Ta (tantalum) and Sb (antimony), with Elements A and B comprising other elements as additives. An X-ray diffraction profile of crushed particles of the piezoceramic composition that are 10 ?m or less in diameter has a diffraction peak indicating the presence of the main (single) phase as well as a heterogeneous phase of a crystalline structure signified as formula AsBtOu (s<t<u) but not belonging to the perovskite structure.

Abstract: This invention provides for a piezoelectric ceramic composition having a lead-free alkaline niobate piezoelectric ceramic composition with a favorable piezoelectric property. This invention refers to a piezoelectric ceramic composition 10 that is described as composition formula {Lix(K1-yNay)1-x}(Nb1-zSbz)O3 including the additives of the metallic elements Bi and Fe within the range of the following relational expressions: 0.03?x?0.045; 0.5?y?0.58; 0.03?z?0.045; and 0.006?v?w?0.010 whereof v is the additive amount of Bi (molar ratio), and w is the additive amount of Fe (molar ratio).

Abstract: This invention provides for a piezoelectric ceramic composition having a lead-free alkaline niobate piezoelectric ceramic composition with a favorable piezoelectric property. This invention refers to a piezoelectric ceramic composition 10 that is described as composition formula {Lix(K1-yNay)1-x}(Nb1-zSbz)O3 including the additives of the metallic elements Bi and Fe within the range of the following relational expressions: 0.03?x?0.045; 0.5?y?0.58; 0.03?z?0.045; and 0.006?v?w?0.010 whereof v is the additive amount of Bi (molar ratio), and w is the additive amount of Fe (molar ratio).

Abstract: An electromechanical transformation device comprises an alkaline niobate piezoelectric ceramic composition and a rigid body adhered onto the major surface of the piezoelectric ceramic composition. The piezoelectric ceramic composition is made of crystal structures such as orthorhombic crystals formed at the side where the temperature is lower than the orthorhombic-to-tetragonal phase transition temperature, tetragonal crystals formed at the side where the temperature is higher than the orthorhombic-to-tetragonal phase transition temperature as well as at the side where the temperature is lower than the tetragonal-to-cubic phase transition temperature, and the cubic crystals formed at the side where the temperature is higher than the tetragonal-to-cubic phase transition temperature.