Optimization technology for resonance phenomena and nonlinear phenomena using ultrasound.
- Experimental and Research Cycle of Abstract Algebra Models and Ultrasonic Phenomena - Technology for Achieving Dynamic Control of Ultrasound
The Ultrasonic System Research Institute has developed a technology for ultrasonic <dynamic control> that optimizes the interaction of ultrasonic vibrations based on various analysis results of ultrasonic propagation states using an original ultrasonic system and an abstract algebra model. Note: The control of resonance phenomena (low harmonics) and nonlinear phenomena (high harmonics) is achieved by setting oscillation control conditions based on a logical model. In contrast to existing control technologies, this technique establishes and implements optimal control states tailored to the purposes of ultrasonic applications (cleaning, stirring, processing, etc.) through new measurement and evaluation parameters (note) concerning the entire propagation path of ultrasonic vibrations, including various propagation tools. This is a method and technology that can be applied immediately, and we offer it as consulting services (there is an increasing track record of precision cleaning and stirring at the nano level). Note: Using original technology (ultrasonic tester), we measure, analyze, and evaluate dynamic changes in the propagation state of water tanks, transducers, target objects, and tools, among others. (Parameters: power spectrum, autocorrelation, bispectrum, power contribution rate, impulse response characteristics, etc.)
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basic information
Basic Concept (Integration of Phenomena and Models) The continuation of vibrational phenomena leads to the growth of resonance phenomena, resulting in the occurrence of larger resonance phenomena. This is accompanied by the decay of resonance phenomena due to the distortion and changes in the vibrational waveform, which gives rise to nonlinear phenomena. As the propagation (flow) of vibrations develops due to nonlinear phenomena, resonance phenomena emerge from the smaller parts of nonlinear phenomena caused by the distribution and variation of propagation, while nonlinear phenomena decay. This process repeats over time. Controlling this cycle becomes the optimization technique for resonance and nonlinear phenomena. By applying this technology, we have developed a new method for manufacturing ultrasonic oscillation control probes that realize the combination of resonance and nonlinear phenomena. Ultrasonic Probe: Overview Specifications - Measurement Range: 0.01 Hz to 200 MHz - Oscillation Range: 1.0 kHz to 25 MHz - Propagation Range: 0.5 kHz to over 700 MHz - Materials: Stainless steel, LCP resin, silicon, Teflon, glass, etc. - Oscillation Equipment: Example - Function Generator
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Applications/Examples of results
Example: Ultrasonic Cleaning For a liquid volume of up to 2000 liters in the tank A tank treated with ultrasonic and fine bubble surface modification Degassing fine bubble generation liquid circulation device: 1 unit ON/OFF control ON: 213 seconds OFF: 31 seconds Base ultrasonic transducer: 1 unit ON/OFF control 40 kHz 600W (output 150W) ON: 57 seconds OFF: 17 seconds Four megahertz ultrasonic oscillation control probes Megahertz ultrasonic oscillation control probe 1: Pulse oscillation 3 MHz (output 10W) Megahertz ultrasonic oscillation control probe 2: Sweep oscillation 60 kHz to 20 MHz (output 12W) Megahertz ultrasonic oscillation control probe 3: Pulse oscillation 11 MHz (output 10W) Megahertz ultrasonic oscillation control probe 4: Sweep oscillation 4 to 20 MHz (output 12W) Example: Ultrasonic Processing Two megahertz ultrasonic oscillation control probes Megahertz ultrasonic oscillation control probe 1: Pulse oscillation 13 MHz (output 10W) Megahertz ultrasonic oscillation control probe 2: Sweep oscillation 5 to 20 MHz (output 10W)
Detailed information
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Ultrasonic oscillation control probe capable of controlling resonance phenomena and nonlinear phenomena -- Abstract algebra model and experimental/investigation cycle of ultrasonic phenomena -- (Optimization technology for resonance phenomena and nonlinear phenomena)
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Ultrasonic Oscillation Control Probe for Controlling Resonance Phenomena and Nonlinear Phenomena -- Abstract Algebra Model and Experimental/Examination Cycle of Ultrasonic Phenomena -- (Optimization Techniques for Resonance Phenomena and Nonlinear Phenomena)
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Ultrasonic Oscillation Control Probe for Controlling Resonance and Nonlinear Phenomena -- Abstract Algebra Model and Experimental/Investigative Cycle of Ultrasonic Phenomena -- (Optimization Techniques for Resonance and Nonlinear Phenomena)
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Ultrasonic oscillation control probe that enables control of resonance phenomena and nonlinear phenomena -- Abstract algebra model and experimental examination cycle of ultrasonic phenomena -- (Optimization technology for resonance phenomena and nonlinear phenomena)
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Ultrasonic Oscillation Control Probe for Controlling Resonance Phenomena and Nonlinear Phenomena -- Abstract Algebra Model and Experimental/Investigative Cycle of Ultrasonic Phenomena -- (Optimization Techniques for Resonance and Nonlinear Phenomena)
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Ultrasonic Oscillation Control Probe for Controlling Resonance and Nonlinear Phenomena -- Abstract Algebra Model and Experimental/Examination Cycle of Ultrasonic Phenomena -- (Optimization Techniques for Resonance and Nonlinear Phenomena)
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Ultrasonic Oscillation Control Probe for Controlling Resonance and Nonlinear Phenomena -- Abstract Algebra Model and Experimental/Examination Cycle of Ultrasonic Phenomena -- (Optimization Techniques for Resonance and Nonlinear Phenomena)
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Ultrasonic Oscillation Control Probe for Controlling Resonance and Nonlinear Phenomena -- Abstract Algebra Model and Experimental/Examination Cycle of Ultrasonic Phenomena -- (Optimization Techniques for Resonance and Nonlinear Phenomena)
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Ultrasonic oscillation control probe that enables control of resonance phenomena and nonlinear phenomena -- Abstract algebra model and experimental/investigation cycle of ultrasonic phenomena -- (Optimization technology for resonance phenomena and nonlinear phenomena)
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Company information
The Ultrasonic System Research Institute conducts the following activities with its original product: ultrasonic systems (sound pressure measurement analysis, oscillation control): 1) Manufacturing and sales of ultrasonic systems (sound pressure measurement analysis, oscillation control) 2) Consulting services for various equipment (Note): cleaning machines, stirring devices, processing equipment, machine tools, plating devices, welding devices, etc. Ultrasonic System (Sound Pressure Measurement Analysis, Oscillation Control) We manufacture and sell a system that combines the "Ultrasonic Tester NA (recommended type)" for easy measurement and analysis of ultrasonic waves and the "Ultrasonic Oscillation System (1 MHz, 20 MHz)" for easy oscillation control. <Patent Applications Filed> Patent Application No. 2021-125866: Ultrasonic Control (Ultrasonic Oscillation Control Probe) Patent Application No. 2021-159990: Ultrasonic Welding Patent Application No. 2021-161532: Ultrasonic Plating Patent Application No. 2021-171909: Ultrasonic Processing Patent Application No. 2021-175568: Flow-type Ultrasonic Cleaning Some of the manufacturing technology for the ultrasonic oscillation control probe is described in Patent Application No. 2021-125866. Patent Application No. 2023-195514: Ultrasonic Plating Using Megahertz Ultrasonic Waves and Fine Bubbles.