Your search keyword '"Ultrasonic power"' showing total 296 results

1. Enhancing condensation droplets removal on tube through periodic ultrasonic vibration

Author

Lu, Weiyan, Shang, Yuhe, Liu, Yanbo, and Li, Dong

Published

2025

2. Understanding the influence of ultrasonic power on the hydration of cement paste

Author

Xiong, Guangqi, Ren, Yuanliang, Jia, Xiaolong, Fang, Zheng, Sun, Keke, Huang, Qian, Wang, Chong, and Zhou, Shuai

Published

2024

3. Effectiveness of Ag@NiO@g-C3N4 photocatalysts: Green fabrication and superior photocatalysis capability

Author

Alharbi, Fayez K., Albadri, Abuzar E.A.E., Modwi, Abueliz, and Saleh, Sayed M.

Published

2024

4. Effect of Different Ultrasonic Power on Microstructure and Mechanical Properties of ZL205A/TiB2 Composite Materials.

Author

Tang, Jingchuan, Omar, Mohd Zaidi, Jiang, Ripeng, Mohamed, Intan Fadhlina, and Li, Anqing

Abstract

High-energy ultrasound plays an important role in enhancing the uniform distribution of reinforcing particles inside the composites. In this work, the effect of different ultrasonic power (0–1000 W) on the solidification microstructure and mechanical properties of 2.0 wt% ZL205A/TiB2 composites was investigated. The experimental results show that, within a certain range, the increase of ultrasonic power can refine the grain size, reduce the TiB2 particle agglomeration, and enhance the mechanical properties of composites. The grain size was reduced from 93 μm (0 W) to 49 μm (800 W), and the tensile strength (UTS) was increased from 186.5 to 230.6 MPa, respectively, a relative increase of 47.3%. However, when the ultrasonic power reaches 1000 W, the microstructure of the composites is deteriorated, the grain size is coarse, and the mechanical properties are reduced. This indicates that high ultrasonic power is not conducive to the further optimization of composite microstructure. Based on the experimental results, the mechanisms of ultrasonic power on the microstructure of the composite materials have been discussed in detail. Furthermore, the quantitative relationships between ultrasonic power and sound pressure (P), the intensity density (I), the acoustic impulse velocity (v), and amplitude (A) was established, which played an important theoretical guidance role for the preparation of metal matrix composite materials during industrial application with ultrasonic treatment. The main objective of this work is to explore the changes in the microstructure and mechanical properties of ZL205A/TiB2 composite materials under the influence of different ultrasonic powers. The lattice matching relationship between TiB2 reinforcement particles and the aluminum matrix is revealed, and the changes in acoustic energy density, sound pressure intensity, and ultrasonic amplitude under different ultrasonic powers are quantitatively analyzed. [ABSTRACT FROM AUTHOR]

Published

2025

5. Effect of Ultrasonic Power on the Microstructure and Properties of a Semi-Solid Slurry of SnSbCu11-6 Alloy.

Author

Wang, Lei, Luo, Xiaobin, Jia, Yuanwei, Li, Yongkun, Zhou, Rongfeng, Zhang, Hao, Huo, Dingdong, and Li, Yao

Subjects

ULTRASONIC effects, PARTICLE size distribution, MELTING points, GRAIN size, TENSILE strength

Abstract

In this paper, the ultrasonic vibration treatment (UVT) technique was used to prepare a SnSbCu11-6 alloy semi-solid slurry, and the effects of ultrasonic power on its microstructure size, distribution and properties were studied. The results show that the UVT technique significantly refines the Cu6Sn5 phase and SnSb phase and improves their distribution uniformity. Interestingly, the second SnSb phase is also well refined to nearly 100 °C below the melting point; furthermore, the morphology is transformed from coarse petal-like to fine regular cubic, and the average grain size is refined to 48.8 ± 8.8 μm. The alloy's comprehensive properties are best when the ultrasonic power is 1200 W. The yield strength, tensile strength, elongation and microhardness reach 60.6 MPa, 70.3 MPa, 4.9% and 27.4 HV, respectively, which represent increases of 4.7%, 6.0%, 113% and 23.4%, respectively, compared with conventional liquid casting. This may be attributed to the grain size refinement and distribution uniformity enhancement of the Cu6Sn5 phase and the SnSb phase. This work provides a feasible and effective method for the preparation of high-performance tin-based babbitt alloys by UVT technology. [ABSTRACT FROM AUTHOR]

Published

2025

6. The Modal and Harmonic Analysis of a Cylindrical Horn Designed for an Airborne Ultrasonic Dryer

Author

Hossein Golbakhshi, Moslem Namjoo, and Mohammad Reza Kamandar

Subjects

ultrasonic power, cylindrical horn, finite element method, modal analysis, Agriculture

Abstract

The extensive radiating surface of horn is an imperative part for amplifying the ultrasonic airborne waves generated for drying of foodstuffs. However, the radiation of high-intensity waves may lead to frequency shift, interaction of modes and reduced efficiency of ultrasonic system. Furthermore, the excitations may also be harmful to the transducer, horn and the joints. In this study, a finite element model is developed for the dynamic analysis of a cylindrical horn. In the modal analysis, the natural frequency of horn is found to be 19,498 Hz which is very close to the working frequency of the ultrasonic generator i.e., 20 kHz. At this frequency, the amplitude of non-beneficial longitudinal mode is negligible compared with that in main radial mode shape and there is no risk for interaction of modes. According to the harmonic analysis, the generated von Mises stresses in the horn are much lower than the endurance limit of constructing material and the horn can safely radiates the waves. The experimental data measured by a laser vibrometer are also used for validating the results of numerical simulation.

Published

2024

7. The Modal and Harmonic Analysis of a Cylindrical Horn Designed for an Airborne Ultrasonic Dryer.

Author

Golbakhshi, Hossein, Namjoo, Moslem, and Kamandar, Mohammad Reza

Subjects

ULTRASONIC waves, MODAL analysis, FINITE element method, HARMONIC analysis (Mathematics), MODE shapes

Abstract

Copyright of Biomechanism & Bioenergy Research is the property of Shahid Bahonar University of Kerman and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

8. Impact of ultrasonic power on evolution mechanism of cavitation effect in water-bearing coal pores microstructure.

Author

Zhang, Lemei, Guo, Xiaoyang, Deng, Cunbao, Wang, Yujuan, Song, Liuni, Li, Yanfeng, and Xu, Jiahua

Subjects

ULTRASONIC waves, GAS migration, ULTRASONIC effects, COALBED methane, NONDESTRUCTIVE testing, CAVITATION

Abstract

Ultrasonic waves have been explored for fracturing coal seams to enhance Coalbed Methane (CBM) permeability, yet the underlying mechanics of ultrasonic cavitation are not fully understood. This study investigates the effect of water-based ultrasonic cavitation on coal pores microstructure by employing fluid invasion methods and non-destructive X-ray testing to reconstruct coal pore microstructures. Additionally, numerical simulations of ultrasonic cavitation development were conducted. The research examines how ultrasonic power influence evolution mechanism of cavitation effects in pores microstructure of water-bearing coal. Such insights lay a theoretical groundwork for improved Water-Based Ultrasonic Cavitation Enhanced Coalbed Methane Recovery (WUC-ECBM). Findings suggest that coal pores microstructure with a fully connected pore topology are more conducive to ultrasonic cavitation. As ultrasonic exposure increases, the accumulated waves cause coal pore microstructure cavitation bubbles to oscillate violently and non-linearly, leading to their growth, development, and collapse. This results in high-energy microjets and shockwaves, creating a high-temperature, high-pressure environment (reaching up to 35.69 MPa and 2729.77 K) favorable for improving gas desorption and migration. Ultrasonic power adjusts the cavitation threshold and intensity, facilitating gas migration. This research aims to improve gas desorption and migration in coal by capitalizing on the mechanical, physical, and thermal effects of ultrasonic cavitation. These findings offer theoretical support for the effective implementation of WUC-ECBM. [ABSTRACT FROM AUTHOR]

Published

2024

9. Effect of Different Ultrasonic Power on Microstructure and Mechanical Properties of ZL205A/TiB2 Composite Materials

Author

Tang, Jingchuan, Omar, Mohd Zaidi, Jiang, Ripeng, Mohamed, Intan Fadhlina, and Li, Anqing

Published

2025

10. Adsorption Capability and Mechanism of Pb(II) Using MgO Nanomaterials Synthesized by Ultrasonic Electrodeposition.

Author

Tang, Dan, Zhang, Quanqing, Tan, Guanglei, He, Lijie, and Xia, Fafeng

Subjects

ADSORPTION (Chemistry), TRANSMISSION electron microscopy, SCANNING electron microscopy, ADSORPTION capacity, X-ray diffraction

Abstract

This work describes the process of synthesizing magnesia (MgO) nanomaterials through ultrasonic electrodeposition, followed by an examination of their ability and mechanism to remove Pb(II) from industrial soil at 100, 150, and 200 W ultrasonic powers. Nanomaterials were examined for their surface shape and phase composition using scanning electron microscopy (SEM), transmission electron microscopy (TEM), and X-ray diffractometry (XRD). The capability of magnesia nanomaterials to adsorb Pb(II) improved greatly when operated at 150 W, attaining a maximal 68.94 mg/g value. Adsorption of Pb(II) onto magnesia nanomaterial surfaces was examined by utilizing the pseudo-second-order kinetic and Langmuir models. The nanomaterials exhibited significant features of both chemical and monolayer adsorptions for Pb(II) as a result of the intense chemical interactions between the atoms of the magnesia nanomaterials' surface and Pb(II), as shown by Fourier transform infrared (FTIR) analysis. At 30 °C, the magnesia nanomaterial exhibited the highest adsorption capacity for Pb(II), suggesting that temperature played a significant role in this capacity. Furthermore, the Langmuir model produced a correlation coefficient greater than 0.99, indicating an excellent fit for the adsorption behavior of magnesia towards Pb(II). The findings suggest that ultrasonic power significantly impacts the adsorption characteristics of magnesia nanoparticles synthesized via ultrasonic electrodeposition. Specifically, ultrasonic power of 150 W yields the most efficient adsorption characteristics. Moreover, the 150 W-fabricated magnesia materials demonstrated exceptional pH compatibility. [ABSTRACT FROM AUTHOR]

Published

2024

11. Effects of different power multi-frequency ultrasound-assisted thawing on the quality characteristics and protein stability of large yellow croaker (Larimichthys crocea)

Author

Xinrui Yang, Chuhan Bian, Yixuan Dong, Jing Xie, and Jun Mei

Subjects

Ultrasound-assisted thawing, Large yellow croaker, Multi-frequency, Ultrasonic power, Myofibrillar protein structure, Nutrition. Foods and food supply, TX341-641, Food processing and manufacture, TP368-456

Abstract

This study investigated the impact of multi-frequency ultrasound-assisted (20/28/40 kHz) thawing (MUAT) at different power levels (195, 220, 245, and 270 W, respectively) on the flesh quality and protein stability of large yellow croakers. Compared with flowing water thawing (FWT) and the other MUAT sample, flesh quality results indicated that the MUAT-220 W significantly reduced (p

Published

2024

12. Proving Bioactive Compounds and Antioxidant Activities of Ajuga remota Benth Leaves Extract: Impact of Ultrasonic Power, Sonication Time, and Conventional Extraction Parameters

Author

Zerihun-Chala Meseret, Admassu-Emire Shimelis, Benjakul Soottawat, Worku-Dadi Debebe, and Temdee Wattana

Subjects

ajuta remota, ultrasonic power, extraction time, bioactive compounds, antioxidant activities, lc/ms, Food processing and manufacture, TP368-456

Abstract

Ajuga remota Benth plant contains a variety of phytochemicals including phenolic compounds with potent antioxidant activities. However, in order to improve the extraction efficiency, green technologies need to be used while extracting bioactive compounds. Therefore, this study was aimed to determine the impact of ultrasonic power and extraction time on the extract yield, bioactive compounds and antioxidant activities of A. remota leaves extract. Ultrasonic assisted extraction (UAE) was employed at amplitude of 50, 60 and 70% with the sonication time of 10 and 20 min. The highest total phenolic content (44.14 mg GAE/g) and flavonoids content (126 mg QE/g), and antioxidant activities 100.11 mg TE/g, 263.97, mg TE/g and 286.19 mg TE/g for DPPH, FRAP and ABTS, respectively, were found at 70 % ultrasonic power with the extraction time of 10 min. Thus, UAE showed a significant (p

Published

2024

13. Numerical simulation and study on heat and mass transfer in a hybrid ultrasound/convective dryer.

Author

Chen, Kaikang, Torki, Mehdi, Ghanbarian, Davoud, Beigi, Mohsen, and Abdelkader, Tarek Kh.

Abstract

Susceptibility of airborne ultrasonic power to augment heat and mass transfer during hot air dehydration of peppermint leaves was investigated in the present study. To predict the moisture removal curves, a unique non-equilibrium mathematical model was developed. For the samples dried at temperatures of 40‒70 °C and the power intensities of 0‒104 kW m−3, the diffusion of moisture inside the leaves and coefficients for of mass and heat transfer varied from 0.601 × 10–4 to 5.937 × 10–4 s−1, 4.693 × 10–4 to 7.975 × 10–4 m s−1 and 49.2 to 78.1 W m−2 K−1, respectively. In general, at the process temperatures up to 60 °C, all the studied transfer parameters were augmented in the presence of ultrasonic power. [ABSTRACT FROM AUTHOR]

Published

2024

14. Effect of Ultrasonic Power on the Microstructure and Properties of a Semi-Solid Slurry of SnSbCu11-6 Alloy

Author

Lei Wang, Xiaobin Luo, Yuanwei Jia, Yongkun Li, Rongfeng Zhou, Hao Zhang, Dingdong Huo, and Yao Li

Subjects

SnSbCu11-6, semi-solid, ultrasonic power, microstructure, properties, Crystallography, QD901-999

Abstract

In this paper, the ultrasonic vibration treatment (UVT) technique was used to prepare a SnSbCu11-6 alloy semi-solid slurry, and the effects of ultrasonic power on its microstructure size, distribution and properties were studied. The results show that the UVT technique significantly refines the Cu6Sn5 phase and SnSb phase and improves their distribution uniformity. Interestingly, the second SnSb phase is also well refined to nearly 100 °C below the melting point; furthermore, the morphology is transformed from coarse petal-like to fine regular cubic, and the average grain size is refined to 48.8 ± 8.8 μm. The alloy’s comprehensive properties are best when the ultrasonic power is 1200 W. The yield strength, tensile strength, elongation and microhardness reach 60.6 MPa, 70.3 MPa, 4.9% and 27.4 HV, respectively, which represent increases of 4.7%, 6.0%, 113% and 23.4%, respectively, compared with conventional liquid casting. This may be attributed to the grain size refinement and distribution uniformity enhancement of the Cu6Sn5 phase and the SnSb phase. This work provides a feasible and effective method for the preparation of high-performance tin-based babbitt alloys by UVT technology.

Published

2024

15. Effect of Ultrasonic Power on the Quality and Myofibrillar Protein Structure of Beef Jerky

Author

DONG Zhiming, YAO Ziyao, JIANG Qiuwan, JIANG Bowen, WANG Jianzhao, CHEN Qian, ZHANG Wentao

Subjects

beef jerky, ultrasonic-assisted curing, ultrasonic power, quality, protein structure, Food processing and manufacture, TP368-456

Abstract

In order to improve the hard texture, poor chewiness and unstable quality of traditional beef jerky, the effect of of ultrasonic power on the quality and myofibrillar protein structure of beef jerky, prepared by ultrasonic-assisted marination at different ultrasonic powers (0, 150, 300, 450 and 600 W) and 30 kHz frequency for 30 min followed by natural fermentation for six days, was explored. The quality characteristics of marinated beef strips and beef jerky such as moisture content, water activity, pH, color, salt content and shear force were evaluated. Meanwhile, changes in the myofibrillar fragmentation index (MFI), surface hydrophobicity, carbonyl group content, and total sulfhydryl and active sulfhydryl group contents of myofibrillar proteins in fresh beef strips after ultrasonic treatment were investigated and sensory evaluation of beef jerky were carried out. Results showed that the pH, moisture content, water activity, salt content, L* value and b* value of beef jerky increased with the increase in ultrasonic power, while the shear force decreased. Ultrasonic treatment increase the a* value, whereas the opposite effect was observed at excessively high ultrasonic power. With the increase in ultrasonic power, the MFI, surface hydrophobicity, active sulfhydryl group content and carbonyl group content of myofibrillar proteins increased, while the total sulfhydryl group content decreased (P < 0.05). Sensory evaluation showed that beef jerky with ultrasonic treatment at 300 W had the best overall acceptability. In summary, to maintain color stability and avoid excessive oxidation of protein and energy waste, an ultrasonic power of 300 W was determined as the optimal treatment condition, which could significantly improve the overall quality of beef jerky.

Published

2023

16. The effect of ultrasonic power on the physicochemical properties and antioxidant activities of frosted figs pectin

Author

Rui-xue Deng, Yi-ying Zheng, Dong-jie Liu, Jing-yi Liu, Meng-nan Zhang, Guang-yuan Xi, Lu-lu Song, and Pu Liu

Subjects

Frosted figs pectin, Ultrasonic power, Physicochemical properties, Antioxidant activity, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

Ultrasound has been widely used in industry due to its high energy and efficiency. This study optimized the ultrasonic-assisted extraction (UAE) process of frosted figs pectin (FFP) using response surface methodology (RSM), and further investigated the effect of ultrasonic power on the structural characteristics and antioxidant activities of FFPs. The UAE method of FFP through RSM was optimized, and the optimal extraction process conditions, particle size of 100 mesh, pH value of 1.95, liquid–solid ratio of 47:1 (mL/g), extraction temperature of 50 °C and extraction time of 65 min, were obtained. The extraction rate of FFP under this condition was 37.97 ± 2.56 %. Then, the four FFPs modified by ultrasound were obtained by changing the ultrasonic power. Research had found that ultrasonic power had little effect on the monosaccharide composition, Zeta potential, as well as the thermal stability and appearance structure of the four FFPs. However, ultrasonic power had a significant impact on other properties of FFP: as the ultrasonic power increased, the DM% and particle size decreased continuously, while the total carbohydrate content increased. Meanwhile, ultrasonic power also had a significant impact on antioxidant activities of FFPs. From the research results, it could be seen that different ultrasonic power had certain changes in its spatial structure and properties, and the structural changes also affected the biological activity of FFP. The study of the effects of ultrasonic power on the physicochemical properties and biological activity of FFP lays the foundation for the development and application of FFP in food additives and natural drug carriers.

Published

2024

17. Inducing Selenium Vacancy in Nickel Selenide/Iron Selenide by Hydrazine‐Ultrasonic Treatment for Electrocatalytic Water Splitting Reaction.

Author

Senapati, Shraddhanjali, Bal, Rajaram, Mohapatra, Manoj, Dalai, Namita, and Jena, Bijayalaxmi

Subjects

WATER purification, SELENIDES, CHARGE transfer kinetics, OXYGEN evolution reactions, NICKEL, SELENIUM, IRON selenides, HYDRAZINE, DEFEROXAMINE

Abstract

Electrocatalyst plays an important role in enhancing the activity of water‐splitting reaction. Researchers are adopting various techniques like composite formation, doping, and creating vacancy, to improve the catalytic activity of the electrocatalyst. Herein, nickel selenide/iron selenide (NiSe2/FeSe2) electrocatalyst is synthesized for electrocatalytic water splitting application, i.e., for oxygen evolution reaction (OER) in 1.0 M KOH electrolytic solution. Further, the activity of the electrocatalyst is enhanced by creating selenium vacancies following a facile reduction method using hydrazine hydrate and simultaneously using ultrasonic power to form the catalyst, namely, Vse‐NiSe2/FeSe2. Vacancy engineering enhances the electrocatalytic activity of NiSe2/FeSe2 by increasing the electrochemical surface area and number of active sites. Pseudospherical Vse‐NiSe2/FeSe2 vacant sites offer insight into the efficient charge transfer and surface kinetics for the OER. [ABSTRACT FROM AUTHOR]

Published

2024

18. Effect of ultrasonic power on microstructure and properties of ultrasonic electrodeposited ZnCo2O4 anode nanomaterials

Author

Dong Liu, Hailong Fu, Xu Zhu, and Longqing Zou

Subjects

Ultrasonic power, ZnCo2O4 anode nanomaterial, Microstructure, Lithium storage, Chemistry, QD1-999

Abstract

Ultrasonic electrodeposition was employed to manufacture ZnCo2O4 anode nanomaterials (ZCOAN), with the objective of utilization as high-performance anode materials for lithium-ion batteries. The influence of ultrasonic power on various characteristics of ZCOAN, including surface morphology, phase composition, crystal structure, and electrochemical properties was also investigated. The results indicated that ZnCo2O4 anode nanomaterials prepared at 600 W demonstrated a spinel surface structure with polyporous dendrite spores and a subcrystalline size of 11.68 nm. Moreover, the prepared ZCOAN material demonstrated polyporous morphological characteristics and well-organized particles. Diffraction peaks were identified at specified angles in all ZCOAN samples: 31.26°, 36.93°, 46.38°, 54.13°, 59.87°, and 66.17° corresponding to the crystallographic planes (200), (311), (400), (422), (511), and (440), respectively. The appearance of these peaks confirms the presence of a spinel structure in the ZCOAN samples. A smaller grain size results in increased gaps and a larger surface area, thereby promoting ion exchange. Therefore, ZnCo2O4 anode nanomaterials synthesized at 600 W showed superior electrochemical performance compared to other samples. They demonstrated the highest charge capacity (∼1176 mAh·g−1), discharge capacity (∼1160 mAh·g−1), and stability, along with a minimal electrical impedance (35.65 Ω) at a constant current density of 150 mA·g−1. Furthermore, the coulomb efficiency of this nanomaterial remained high at 98.6 % after 1200 cycles, indicating its excellent cycling performance.

Published

2024

19. In-situ temperature monitoring during rotary ultrasonic-assisted drilling of fiber-reinforced composites.

Author

Shard, Abhinav, Agarwal, Raj, Garg, Mohinder Pal, and Gupta, Vishal

Subjects

*DELAMINATION of composite materials, *FIBROUS composites, *RESPONSE surfaces (Statistics), *MANUFACTURING processes, *COMPOSITE materials, *TEMPERATURE, *ANALYSIS of variance

Abstract

Drilling polyetherimide composite is difficult due to the anisotropic and inhomogeneous structure of fiber and matrix. Drilling of fiber-reinforced composites is a thermo-mechanical friction procedure required in various aerospace and automotive applications. The major reason for component rejection during manufacturing processes is due to thermal damage and temperature elevation defects such as delamination and fiber pullout caused during drilling. This work aims to propose a rotary ultrasonic-assisted drilling technique for composite materials to reduce thermal damage using diamond-impregnated tools. The influence of drilling parameters such as rotational speed, feed rate, abrasive grit size, and ultrasonic power was monitored on temperature elevations. The temperature was monitored using thermocouples located at different distances of 1.0, 2.0, and 3.0 mm from the main drilled hole. The response surface methodology was used for the design of experiments during the drilling of composite material and optimization of process parameters was carried out using analysis of variance. Rotational speed and abrasive grit size were observed to have the highest contribution of 42% and 37% for temperature elevations respectively. It was witnessed that temperature increases with an increase in rotational speed, feedrate, and abrasive grit size. Increasing the ultrasonic power during drilling temperature can be minimized. The temperature elevations at the tool-composite interface can be reduced by leveraging the application of rotary ultrasonic-assisted drilling. [ABSTRACT FROM AUTHOR]

Published

2023

20. 超声功率对牛肉干品质及牛肉肌原纤维 蛋白结构的影响.

Author

董智铭, 么紫瑶, 姜萩婉, 蒋博文, 王见钊, 陈倩, and 张文涛

Subjects

WESTERN countries, DRIED beef, SULFHYDRYL group, ULTRASONIC effects, BEEF quality, CARBONYL group

Abstract

Copyright of Shipin Kexue/ Food Science is the property of Food Science Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

21. Application of Ultrasonic Power in Forming Sn58Bi/Cu Solder Joints with Trace Si3N4 Nanowire Doping

Author

Chen, Chen, Zhang, Liang, Chen, Mo, Huang, Xi, and Wu, Chuan-jiang

Published

2024

22. Experimental study on damage characteristics and energy evolution of coal by ultrasonic power

Author

LI Shugang, WANG Ruizhe, LIN Haifei, YANG Erhao, ZHAO Hongchao, QIN Lei, and HAO Hejie

Subjects

ultrasonic power, coal mechanics, uniaxial compression, acoustic emission, fractal dimension, damage mechanism, Mining engineering. Metallurgy, TN1-997

Abstract

In order to study the mechanical damage characteristics and energy evolution law of coal after ultrasonic fracturing, uniaxial compression experiments were carried out on fractured coal with different power by using electronic universal pressure testing machine, acoustic emission system. The mechanical damage parameters of different power ultrasonic fracturing coal were obtained, and the relationship between acoustic emission signal and damage parameters of coal mass with different power fracturing was explored. The fractal characteristics of coal surface cracks were analyzed by box fractal dimension, and the damage degradation mechanism of ultrasonic fracturing coal caused by different ultrasonic power was clarified. The experimental results show that the characteristic strength and elastic modulus of coal gradually decrease with the increase of ultrasonic fracturing power, and the damage parameters of uniaxial compressive strength and elastic modulus of coal are linearly correlated with the fracturing power. During the uniaxial compression process, the acoustic emission ringing count can be divided into three stages, which are quiet period, rising period and fluctuating period. With the increase of ultrasonic power, the incubation period of crack is shorter and the proportion of relative time is smaller. With the increase of crack growth rate, the weakening effect on the strength of coal is gradually enhanced, the sudden increase of acoustic emission signal is obvious., the final failure of coal sample is more broken, and the failure characteristics change from elastic brittleness to ductility-plasticity with the increase of fracturing power. Coal pore fissure extension, and three is a linear positive correlation between the fractal dimension damage parameters of coal surface cracks and the fracturing power. The greater the fractal dimension damage parameter is, the more complex the coal fracture morphology is. Based on the acoustic parameters, the relationship between the damage parameters and the normalized parameters of acoustic emission is analyzed, and it has a good fitting relationship. The above results show that ultrasonic fracturing causes damage to the coal structure, makes the coal seam damage and deformation, and forms a complex coal seam seepage network, thus improving the permeability of coal seam.

Published

2023

23. Curcumin-loaded oil body emulsions prepared by an ultrasonic and pH-driven method: Fundamental properties, stability, and digestion characteristics

Author

Jianyu Zhu, Huan Wang, Liming Miao, Ning Chen, Qing Zhang, Ziheng Wang, Fengying Xie, Baokun Qi, and Lianzhou Jiang

Subjects

Oil bodies, Curcumin, Ultrasonic power, Stability, Digestion, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

In this study, oil bodies (OBs) loaded with curcumin (Cur) were successfully prepared via an ultrasonic and pH-driven method. Ultrasonic treatment significantly improved the encapsulation efficiency (EE) and loading capacity (LC) of Cur, producing OB particles with small size, uniform distribution, and high ζ-potential absolute values. When the ultrasonic power was 200 W, the EE, LC, and ζ-potential absolute value were the greatest (88.27 %, 0.044 %, and −25.71 mV, respectively), and the OBs possessed the highest yellowness, representing the best treatment result. The confocal laser scanning microscopy (CLSM) and cryo-scanning electron microscopy (cryo-SEM) results was also intuitionally shown that. Moreover, circular dichroism (CD) proved that ultrasonic treatment could unfold the surface protein structure, further enhancing the stability. Therefore, the cream index (CI), peroxide value (POV), and thiobarbituric acid reactive substances (TBARS) were the lowest when the ultrasonic power was 200 W. In this case, the Cur loaded in OBs was well protected against hostile conditions, evidenced by the highest Cur retention rate and the lowest degradation rate constant. Finally, the in vitro gastrointestinal digestion simulation results showed that the ultrasonic treatment effectively increased the release of FFA, bioaccessibility, and stability of Cur, especially when the ultrasonic power was 200 W. This research offers a new OB-based delivery system to stabilize, deliver, and protect Cur for food processing.

Published

2023

24. Quantitation and evaluation of NO2−, NO3−, and H2O2 in the sonolysis of aqueous NaOH solution under air and air-Ar mixture: Effects of solution temperature, ultrasonic power, and ratio of gas mixture

Author

Kenji Okitsu, Riki Kunichika, and Shota Asada

Subjects

N2 oxidation, NO3−, NO2−, H2O2, Solution temperature, Ultrasonic power, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

When an aqueous solution containing dissolved air is sonicated, H2O2, HNO2, and HNO3 are formed. This is a result of the formation of active bubbles with extremely high-temperature and high-pressure. The yields of H2O2, NO2−, and NO3− are representative indexes for understanding the chemical effects of ultrasonic cavitation in water. However, these yields often vary under the acidic conditions caused by sonication. In this study, we measured the yields of H2O2, NO2−, and NO3− in the presence of NaOH, which suppresses the reaction between NO2− and H2O2 and prevents the formation of NO3− in a bulk solution. Therefore, the yields obtained should correspond to the actual yields just after bubble collapse, directly reflecting the chemical effects of the active bubbles themselves. It was confirmed that the yields of NO2− and NO3− decreased, while the ratio of [NO3−] to [NO2−] ([NO3−]/[NO2−] ratio) increased with increasing solution temperature, suggesting that the temperature and pressure in collapsing bubbles decreased with an increase in the solution temperature. Ultrasonic power clearly affected the yields of NO2− and NO3−, but it did not affect the [NO3−]/[NO2−] ratio, suggesting that 1) the quality of the active bubbles did not change largely with increasing ultrasonic power, and 2) the quantity related to the number and/or size of active bubbles increased with increasing ultrasonic power up to a certain power. Additionally, the effects of the ratio of air to Ar on the yields of NO2−, NO3−, and H2O2 were investigated. These yields could be affected not only by the bubble temperature but also by the concentration of reactants and intermediates inside the collapsing bubbles. The chemical reactions are quite complex, but these yields could be valuable analytical tools for understanding the quantity and quality of active bubbles.

Published

2023

25. Effects of Process Parameters on Bond Properties of Ag-2.35Au-0.7Pd-0.2Pt-0.1Cu Alloy Wire.

Author

Zhou, Hongliang, Chang, Andong, Fan, Junling, Cao, Jun, Zhang, Yingchong, An, Bin, and Xia, Jie

Subjects

ULTRASONIC bonding, WIRE, INTERMETALLIC compounds, ULTRASONIC effects, CUBIC equations, SCANNING electron microscopy

Abstract

Bond properties were performed on Ag-2.35Au-0.7Pd-0.2Pt-0.1Cu alloy wire with a diameter of 25 µm under different process parameters. The effects of electrical flaming off (EFO) current and EFO time on the deformability of the free air ball (FAB) were investigated using scanning electron microscopy (SEM), as well as the effects of ultrasonic power and bonding force on the bond characteristic. The experimental results show that FAB grows from a preheated tip to a small ball, a regular ball, and finally to a golf ball with increasing either the EFO current or the EFO time, and the FAB presents an optimal shape at 25 mA and 650 μs. Moreover, a nonlinear relationship between FAB diameter and EFO time is obtained at an EFO current of 25 mA, which could be expressed by a cubic equation. Further, at a constant bonding force, as the ultrasonic power increased, the mashed ball diameter grew larger and larger, the capillary hole imprint became more and more obvious, and the tail width also increased, and vice versa. The optimal ultrasonic power and bonding force are 70 mW and 45 gf for ball bonding and 90 mW and 75 gf for wedge bonding, respectively. Finally, for all the bonded wire samples prepared under optimal process parameters, no ball and wedge bond lifts happened after the destructive pull test, and full intermetallic compound coverage with perfect morphology occurred on the bond pad after the ball shear test, which meant that the bonded wire samples had high bond strength and hence improved the reliability of microelectronic products. It provided technical support for the reliability research of Pt-containing Ag-based bonding alloy wires. [ABSTRACT FROM AUTHOR]

Published

2023

26. Designing, Manufacturing and Testing an Ultrasound-Assisted Essential Oil Extraction Machine

Author

Duc, Le Anh, Cavas-Martínez, Francisco, Editorial Board Member, Chaari, Fakher, Series Editor, di Mare, Francesca, Editorial Board Member, Gherardini, Francesco, Series Editor, Haddar, Mohamed, Editorial Board Member, Ivanov, Vitalii, Series Editor, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Long, Banh Tien, editor, Kim, Hyung Sun, editor, Ishizaki, Kozo, editor, Toan, Nguyen Duc, editor, Parinov, Ivan A., editor, and Kim, Yun-Hea, editor

Published

2022

27. Sonochemical formation of peroxynitrite in water: Impact of ultrasonic frequency and power

Author

Hamza Ferkous, Oualid Hamdaoui, and Christian Pétrier

Subjects

Peroxynitrite, Sonolysis, Frequency, Ultrasonic power, Dosimetry, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

There is a lack of literature on peroxynitrite formation due to sonolysis of aerated water. In this work, the impact of sonication parameters, frequency and power, on ultrasonic peroxynitrite production in aerated alkaline water was investigated. Peroxynitrite formation was clearly established with undeniable evidence at all the tested frequencies in the range of 516–1140 kHz with a typical G-value (energy-specific yield) of 0.777 × 10−10, 0.627 × 10−10, 0.425 × 10−10 and 0.194 × 10−10 mol/J at 516, 558, 860 and 1140 kHz, respectively. The ultrasonication frequency has a direct impact on the sonochemical peroxynitrite production. Increasing the ultrasonication frequency in the interval 321–1140 kHz reduces peroxynitrite formation. The most practical sonochemistry dosimetries, including hydrogen peroxide production, triiodide dosimetry, Fricke dosimetry, and 4-nitrocatechol formation, were compared with the sonochemical efficiency of the reactors used to produce peroxynitrite. The G-value, energy specific yield, for the tested dosimetries was higher than that for peroxynitrite formation, regardless of frequency. For all chemical dosimetries investigated, the same trend of frequency dependence was found as for peroxynitrite generation. The influence of ultrasonication power on peroxynitrite formation by sonication at diverse frequencies in the interval 585–1140 kHz was studied. No peroxynitrite was formed at lower acoustic power levels, regardless of frequency. As the frequency increases, more power is required for peroxynitrite formation. The production of peroxynitrite increased as the acoustic power increased, despite the frequency of ultrasonic waves. Ultrasonic power is a key factor in the production of peroxynitrite by sonolysis. Since peroxynitrite is uniformly distributed in the bulk solution, peroxynitrite-sensitive solutes can be transformed both in the bulk of the solution and in the surfacial region (shell) of the cavitation bubble. The formation of peroxynitrite should be taken into account in sonochemistry, especially at higher pH values. Ultrasonic peroxynitrite formation in alkaline solution (pH 12) can be considered as a kind of chemical dosimetry in sonochemistry.

Published

2023

28. Influence of ultrasonic power modulation on the optimisation of aluminium alloy micro-arc oxidation coating properties.

Author

Liu, Zhenhua, Lu, Hailin, Zhao, Ziyue, Zhu, Zhiqiang, and Li, Suobin

Subjects

*ULTRASONIC effects, *SUBSTRATES (Materials science), *WEAR resistance, *COATING processes, *ALUMINUM alloys, *CAVITATION erosion, *ELECTRIC arc

Abstract

[Display omitted] • Micro-arc oxidation technology for ultrasonic assistance, control the ultrasonic power size, can obtain a uniform and dense surface, low porosity coating. • The control of ultrasonic power can improve the hardness of the coating, as well as increase the adhesion of the coating and the substrate. • By controlling the ultrasonic power, the roughness of the coating is effectively reduced and the wear resistance is improved. • By controlling the ultrasonic power, coatings with excellent corrosion resistance can be obtained. Conventional micro-arc oxidation (MAO) technology, due to the randomness and transient nature of arc discharge, produces coatings with numerous defects, poor abrasion resistance, and inadequate ability to effectively block the intrusion of corrosive media. In this paper, ultrasonic-assisted technology was used to study the effect of different ultrasonic power regulation on the performance optimization of MAO coating on 6061 aluminum alloy. The coating microstructure and elemental composition were characterized by X-ray diffraction, scanning electron microscopy and energy dispersive spectrometer, and its hardness, wear resistance, corrosion resistance and other properties were tested. The results show that the prepared coating has the characteristics of high hardness, good wear resistance and excellent corrosion resistance under the assistance of ultrasonic power of 50 W. This is mainly attributed to the cavitation effect, mechanical effect and thermal effect generated by the corresponding ultrasonic power, which effectively enhances the surface quality, performance and service life of the coating. This study provides valuable insights into the interaction between ultrasound power and the resulting MAO coatings, and has important implications for optimizing ultrasound-assisted processes and improving coating properties. [ABSTRACT FROM AUTHOR]

Published

2025

29. Effect of frequency and power on the piezocatalytic and sonochemical degradation of dyes in water

Author

Franziska Bößl, Valentin C. Menzel, Efthalia Chatzisymeon, Tim P. Comyn, Peter Cowin, Andrew J. Cobley, and Ignacio Tudela

Subjects

Piezocatalysis, Sonochemistry, Dye degradation, Cavitation, Ultrasonic frequency, Ultrasonic power, Chemical engineering, TP155-156

Abstract

For the very first time, the effect of frequency on the piezocatalytic degradation of dyes has been systematically evaluated. To achieve this, a combination of systems and experimental setups operating at different ultrasonic frequencies ranging from 20 kHz up to 1 MHz were used. In addition, the effect of ultrasonic power was investigated at a low ultrasonic frequency of 20 kHz and higher ultrasonic frequency of 576 kHz to shed more light into the controversial discussion surrounding the ‘true’ mechanisms behind piezocatalysis. The results revealed that mechanical effects derived from acoustic cavitation, predominant at lower ultrasonic frequencies (100 kHz), the chemical effects derived from acoustic cavitation were so remarkable, that it raised the question of whether a piezocatalyst is really necessary when the optimisation of frequency and power may be enough for sonochemistry to fully degrade organic pollutants at a fast rate (pseudo first-order degradation reaction rate constant up to 0.037 min−1).

Published

2023

30. Synthesis of Mesoporous Ru-ZnO@g-C 3 N 4 Nanoparticles and Their Photocatalytic Activity for Methylene Blue Degradation.

Author

Albadri, Abuzar E. A. E., Aissa, Mohamed Ali Ben, Modwi, Abueliz, and Saleh, Sayed M.

Subjects

PHOTOCATALYSTS, X-ray photoelectron spectroscopy, NANOPARTICLES, ORGANIC dyes, WATER pollution, RUTHENIUM catalysts

Abstract

Cleaning contaminated water under light with a novel type of heterogeneous photocatalysts is regarded as a critical method for wastewater resolution. Thus, a unique mesoporous Ru-ZnO@g-C3N4 nanocomposite with an increased surface area was synthesized through the ultrasonic technique in the presence of methanol. The X-ray diffraction pattern efficiently validated the crystal structure of the Ru-ZnO hybrid and allowed it to be integrated into the g-C3N4 structure. TEM imaging revealed the Ru-ZnO nanocomposite as spherical particles spread uniformly throughout the g-C3N4 nanosheet. X-ray photoelectron spectroscopy (XPS) was applied to determine the bonding properties of the samples. Under visible illumination, the synthesized nanocomposites of Ru-ZnO@g-C3N4 were evaluated as a new effective photocatalyst for degrading organic pigments in aquatic conditions. [ABSTRACT FROM AUTHOR]

Published

2023

31. 超声波功率对煤体损伤特性及能量演化规律的试验研究.

Author

李树刚, 王瑞哲, 林海飞, 杨二豪, 赵泓超, 秦　雷, and 郝荷杰

Subjects

ACOUSTIC emission, ELASTIC modulus, FRACTURE mechanics, FRACTAL dimensions, SURFACE cracks, COMPRESSIVE strength

Abstract

Copyright of Coal Science & Technology (0253-2336) is the property of Coal Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

32. 钛合金薄壁件超声振动辅助铣削工艺研究.

Author

于福权 and 方振龙

Abstract

Aiming at the problems of large deformation and low machining accuracy in milling thin-walled titanium alloy parts, an auxiliary milling process based on ultrasonic vibration was proposed. Firstly, the cutting deformation mechanism of titanium alloy was analyzed, and the key factors affecting the workpiece deformation were found out, which provided a reference for the subsequent parameter index analysis. Then, the deformation and stress of titanium alloy thin-walled parts were analyzed by using ABAQUS finite element simulation software, and the action mechanism of ultrasonic vibration and its influence on cutting force were discussed. Finally, the influence of different process parameters on the milling deformation of thin-walled parts under ultrasonic assisted conditions was studied by single factor experiment. The results show that ultrasonic vibration assisted machining can effectively solve the problem of milling deformation of thin-walled parts and greatly improve the machining accuracy. With the increase of spindle speed and ultrasonic power, the deformation of thin-walled parts decreases gradually. With the increase of feed speed, the deformation of thin-wall increases gradually. The experimental and simulation results are basically consistent, and the average error between the experimental and theoretical values is less than 5%, which provides a reference for the selection and optimization of parameters in the milling of titanium alloy thin-walled parts. [ABSTRACT FROM AUTHOR]

Published

2023

33. Effect of Water Flow Rate on Operating Frequency and Power During Acoustic Chamber Tuning

Author

Nag, Akash, Stolárik, Gabriel, Svehla, Brano, Hloch, Sergej, Cavas-Martínez, Francisco, Series Editor, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Haddar, Mohamed, Series Editor, Ivanov, Vitalii, Series Editor, Kwon, Young W., Series Editor, Trojanowska, Justyna, Series Editor, di Mare, Francesca, Series Editor, Hloch, Sergej, editor, Klichová, Dagmar, editor, Pude, Frank, editor, Krolczyk, Grzegorz M., editor, and Chattopadhyaya, Somnath, editor

Published

2021

34. Effect of ultrasound combined with edible coating based on guar gum on the physicochemical quality and texture of fried zucchini slices.

Author

Salehi F, Amiri M, and Ghazvineh S

Subjects

Ultrasonic Waves, Cooking, Water analysis, Sunflower Oil chemistry, Soybean Oil chemistry, Plant Gums, Cyamopsis chemistry, Cucurbita chemistry, Food Technology methods

Abstract

Edible coating (EC) can reduce excessive oil absorption in deep-fat fried food products. Ultrasound is an efficient pretreatment to preserve the quality characteristics of fried samples. The impact of guar gum based EC and sonication on the quality parameters of fried zucchini slices was investigated. The frying time, moisture percent, oil absorption, texture hardness, surface area change, crust color parameters (lightness, redness, yellowness, and total color change), and sensory attributes were assessed after the frying process. EC with guar gum and ultrasonic pretreatment significantly increased the frying time of the slices (p < 0.05). Ultrasonic power (75 or 150 W) did not have a significant impact on changing the frying time and moisture content of fried zucchini pieces (p > 0.05). The guar gum based EC and sonication process reduces the oil absorption in samples by reducing water evaporation. The highest (17.87%) and lowest (12.19%) oil absorption were for the uncoated and coated-high-power-sonicated (150 W) fried zucchini slices, respectively. The high-power ultrasound pretreatment significantly decreased the hardness of fried zucchini pieces (p < 0.05). High-intensity ultrasonic pretreatment (150 W) significantly decreased the crust area change of fried zucchini slices (p < 0.05). The maximum lightness (82.54) and yellowness (41.25) indexes, the minimum redness (-7.24), and total color change (10.68) indexes were for the coated and high-power sonicated (150 W) slices. The highest appearance, odor, texture, flavor, and overall acceptance were for the coated and low-power sonicated (75 W) sample. PRACTICAL APPLICATION: Ultrasound can induce various physicochemical effects, which can modify the structural properties of food products. Ultrasound (5 min, ultrasound bath 40 kHz and 75 W) with guar gum dispersion (1%, w/v) was an efficient treatment for maintaining the quality attributes of fried zucchini slices. The combined edible coating-sonication method can be used to reduce oil absorption, improve the physical properties of fried zucchini slices, and produce better quality product properties than traditional frying., (© 2025 Institute of Food Technologists.)

Published

2025

35. Effect of ultrasonic power on the stability of low-molecular-weight oyster peptides functional-nutrition W1/O/W2 double emulsion

Author

Jinzhen Li, Shuo Wang, Hua Wang, Wenhong Cao, Haisheng Lin, Xiaoming Qin, Zhongqin Chen, Jialong Gao, Leiyan Wu, and Huina Zheng

Subjects

Ultrasonic power, Low-molecular-weight oyster peptides, Double emulsion, Electronic nose, Stability, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

Ultrasonic-assisted treatment is an eco-friendly and cost-effective emulsification method, and the acoustic cavitation effect produced by ultrasonic equipment is conducive to the formation of stable emulsion. However, its effect on the underlying stability of low-molecular-weight oyster peptides (LOPs) functional-nutrition W1/O/W2 double emulsion has not been reported. The effects of different ultrasonic power (50, 75, 100, 125, and 150 W) on the stability of double emulsions and the ability to mask the fishy odor of LOPs were investigated. Low ultrasonic power (50 W and 75 W) treatment failed to form a well-stabilized double emulsion, and excessive ultrasound treatment (150 W) destroyed its structure. At an ultrasonic power of 125 W, smaller particle-sized double emulsion was formed with more uniform distribution, more whiteness, and a lower viscosity coefficient. Meanwhile, the cavitation effect generated by 125 W ultrasonic power improved storage, and oxidative stabilities, emulsifying properties of double emulsion by reducing the droplet size and improved sensorial acceptability by masking the undesirable flavor of LOPs. The structure of the double emulsion was further confirmed by optical microscopy and confocal laser scanning microscopy. The ultrasonic-assisted treatment is of potential value for the industrial application of double emulsion in functional-nutrition foods.

Published

2023

36. Fabrication of Mesoporous V 2 O 5 @g-C 3 N 4 Nanocomposite as Photocatalyst for Dye Degradation.

Author

Saleh, Sayed M., Albadri, Abuzar E. A. E., Aissa, Mohamed Ali Ben, and Modwi, Abueliz

Subjects

X-ray photoelectron spectroscopy, ULTRAVIOLET spectroscopy, COLOR removal in water purification, NANOCOMPOSITE materials, NANOPARTICLES, PHOTOCATALYSTS, DYES & dyeing

Abstract

This study investigated the photocatalytic degradation of RB dye by V2O5@g-C3N4 nano-catalysts. The sonication method was utilized to create V2O5@g-C3N4 nano-catalysts. V2O5@g-C3N4 nano-catalysts were characterized using X-ray diffraction (XRD), energy dispersive spectroscopy (EDS), high-resolution electron microscopy (TEM), BET-surface area analyzer, X-ray photoelectron spectroscopy (XPS), and ultraviolet spectroscopy. In the meantime, the photocatalytic activity, pH, and photocatalyst dosage are investigated in depth to account for RB dye decolorization. The rate constant for RB dye photodegradation was 0.0517 (min−1) and the decolorization rate was 93.4%. The degrading efficiency of RB dye by V2O5@g-C3N4 nanocatalysts is consistent with pseudo-first-order kinetics. The results of this study demonstrated that V2O5@g-C3N4 nanocatalysts are particularly effective at destroying dyes in water. [ABSTRACT FROM AUTHOR]

Published

2022

37. Effects of Process Parameters on Bond Properties of Ag-2.35Au-0.7Pd-0.2Pt-0.1Cu Alloy Wire

Author

Hongliang Zhou, Andong Chang, Junling Fan, Jun Cao, Yingchong Zhang, Bin An, and Jie Xia

Subjects

bond properties, EFO current, EFO time, ultrasonic power, bonding force, Mechanical engineering and machinery, TJ1-1570

Abstract

Bond properties were performed on Ag-2.35Au-0.7Pd-0.2Pt-0.1Cu alloy wire with a diameter of 25 µm under different process parameters. The effects of electrical flaming off (EFO) current and EFO time on the deformability of the free air ball (FAB) were investigated using scanning electron microscopy (SEM), as well as the effects of ultrasonic power and bonding force on the bond characteristic. The experimental results show that FAB grows from a preheated tip to a small ball, a regular ball, and finally to a golf ball with increasing either the EFO current or the EFO time, and the FAB presents an optimal shape at 25 mA and 650 μs. Moreover, a nonlinear relationship between FAB diameter and EFO time is obtained at an EFO current of 25 mA, which could be expressed by a cubic equation. Further, at a constant bonding force, as the ultrasonic power increased, the mashed ball diameter grew larger and larger, the capillary hole imprint became more and more obvious, and the tail width also increased, and vice versa. The optimal ultrasonic power and bonding force are 70 mW and 45 gf for ball bonding and 90 mW and 75 gf for wedge bonding, respectively. Finally, for all the bonded wire samples prepared under optimal process parameters, no ball and wedge bond lifts happened after the destructive pull test, and full intermetallic compound coverage with perfect morphology occurred on the bond pad after the ball shear test, which meant that the bonded wire samples had high bond strength and hence improved the reliability of microelectronic products. It provided technical support for the reliability research of Pt-containing Ag-based bonding alloy wires.

Published

2023

38. The effect of temperature and ultrasonic power on the microstructure evolution of coal modified by clean fracturing fluid: An experimental study.

Author

Zuo, Shaojie, Wang, Changwei, Si, Junting, Zhang, Liang, Tian, Feng, Peng, Shouqing, and Li, Zhonghui

Subjects

*POROSITY, *FRACTURING fluids, *FOURIER transform infrared spectroscopy, *CHEMICAL structure, *ULTRASONIC effects

Abstract

Ultrasonic-assisted fracturing permeability enhancement technology offers several advantages, including a broad range of hydraulic fracturing permeability enhancement, microstructure modified by fracturing fluid, and ultrasonic promotion of gas desorption and extraction. This technology can significantly improve the efficiency of coalbed methane extraction and has broad application prospects. To investigate the effect of ultrasonic action power and temperature on the microstructure evolution of coal by using clean fracturing fluid, experiments were conducted using coal samples from a mine in Shenyang. The pore structure of these samples was analyzed by scanning electron microscopy (SEM) and mercury intrusion method (MIP), while the chemical microstructure was evaluated with energy dispersive spectroscopy (EDS), X-ray diffraction experiment (XRD) and Fourier transform infrared spectroscopy (FTIR). The results showed that ultrasonic treatment improved the pore structure characteristics and connectivity by facilitating chemical reactions between fracturing fluid and mineral impurities. Specifically, when the ultrasonic parameter was set at 600W-60 °C, the pore volume of coal samples increased by 26.09 %, tortuosity decreased by 31.81 %, pore fractal dimension increased by 3.93 %, permeability increased by 100.45 %, aromaticity increased by 16.69 %, and the degree of branching aliphatic side-chains increased by 108.70 %. Under the same ultrasonic power, the effective temperature for ultrasonic-assisted fracturing fluid treatment on coal rock was found to be 60 °C. Additionally, under the same temperature conditions, an increase in ultrasonic power resulted in significant enhancements in both pore structure parameters and chemical structure parameters in coal, showing a certain linear relationship. The research results enrich the theoretical system of coalbed methane mining and provide theoretical guidance for the field practice of this technology. • The pore structure and chemical microstructure of coal under different conditions were analyzed. • There exists an optimal temperature for ultrasonic-assisted fracturing fluid when modifying coal. • The permeability increment was 100.45 % at 600 W-60 °C. [ABSTRACT FROM AUTHOR]

Published

2024

39. Ultrasonic Power Supply of Oil-Water Separation System

Author

Wang, AnHua, Wan, DongDong, Ding, HongKai, Akan, Ozgur, Editorial Board Member, Bellavista, Paolo, Editorial Board Member, Cao, Jiannong, Editorial Board Member, Coulson, Geoffrey, Editorial Board Member, Dressler, Falko, Editorial Board Member, Ferrari, Domenico, Editorial Board Member, Gerla, Mario, Editorial Board Member, Kobayashi, Hisashi, Editorial Board Member, Palazzo, Sergio, Editorial Board Member, Sahni, Sartaj, Editorial Board Member, Shen, Xuemin (Sherman), Editorial Board Member, Stan, Mircea, Editorial Board Member, Jia, Xiaohua, Editorial Board Member, Zomaya, Albert Y., Editorial Board Member, Jiang, Xiaolin, editor, and Li, Peng, editor

Published

2020

40. The Utilization of Ultrasound for Improving Oil Recovery and Formation Damage Remediation in Petroleum Reservoirs: Review of Most Recent Researches.

Author

Otumudia, Ephraim, Hamidi, Hossein, Jadhawar, Prashant, and Wu, Kejian

Subjects

*PETROLEUM reservoirs, *ENHANCED oil recovery, *ULTRASONIC imaging, *PETROLEUM industry, *OIL wells

Abstract

The ultrasound method is a low-cost, environmentally safe technology that may be utilized in the petroleum industry to boost oil recovery from the underground reservoir via enhanced oil recovery or well stimulation campaigns. The method uses a downhole instrument to propagate waves into the formation, enhancing oil recovery and/or removing formation damage around the wellbore that has caused oil flow constraints. Ultrasonic technology has piqued the interest of the petroleum industry, and as a result, research efforts are ongoing to fill up the gaps in its application. This paper discusses the most recent research on the investigation of ultrasound's applicability in underground petroleum reservoirs for improved oil recovery and formation damage remediation. New study areas and scopes were identified, and future investigations were proposed. [ABSTRACT FROM AUTHOR]

Published

2022

41. Comparison of transversal versus torsional mode phacoemulsification for removal of hard cataracts.

Author

Ucgul, Ahmet Yucel and Ucgul, Rukiye Kilic

Subjects

CATARACT surgery, PHACOEMULSIFICATION, INTRAOCULAR pressure, PATIENTS' attitudes, POSTOPERATIVE period

Abstract

Aim: To compare the efficacy and safety profiles of phacoemulsification machines using transversal and torsional ultrasonic power in hard cataract surgery. Methods: The medical records of patients having NO4-6 grade hard cataract based on the Lens Opacification Classification System III, and thereby, operated by using Whitestar Signature (with transversal ultrasonic power) or Infiniti Ozil IP (with torsional ultrasonic power) phacoemulsification machines were retrospectively reviewed. At baseline, best-corrected visual acuity (BCVA), cataract grade, intraocular pressure (IOP), central corneal thickness (CCT), and biometric parameters such as lens thickness or anterior chamber depth were noted. Intraoperatively, total phaco needle time and total surgery time were recorded. Postoperatively, corneal edema severity, BCVA, IOP, and CCT was examined at first, 7th and 30th days. Results: Ninety-eight eyes of 98 patients with an average age of 69.5±10.9 (47-88) years and an average follow-up time of 3.0±1.4 (1-6) months were included into the study. Total phaco needle time and surgery time were significantly shorter in the torsional US group compared to the transversal US group (112±46 vs 171±42 seconds and 9.2±3.5 vs 13.4±3.3 minutes, respectively, both p<0.001). Severe postoperative corneal edema was more common in patients in the transversal US group compared to the torsional US group. Conclusion: Transversal ultrasonic power is more likely to cause corneal edema in patients with hard cataract possibly due to increased phaco needle time and surgery time, compared to torsional ultrasonic power. Therefore, torsional ultrasonic power-based phacoemulsification machines should be the first option, in patients whose corneas at risk of decompensation. [ABSTRACT FROM AUTHOR]

Published

2022

42. Effect of Ultrasonic Power on Microstructure and Properties of Ultrasonic-Assisted Electrodeposited Ni–Al2O3 Thin Nanocoatings.

Author

Ma, Chunyang, Li, Huaxing, Xia, Fafeng, and Xiao, Zhongmin

Abstract

In this work, Ni–Al2O3 thin nanocoatings (TNCs) containing γ-Al2O3 nanoparticles were fabricated by ultrasonic-agitated electrodeposition (UAE). The influence of ultrasonic power on the microstructure, surface topography, phase structure, microhardness, and wear and corrosion performance was also discussed in detail. These results demonstrated that ultrasonic power had a considerable influence on the surface microstructures of the Ni–Al2O3 TNCs. At an ultrasonic power of 300 W, the microstructure of the NA-3 TNC changed significantly; the surface was compact, fine, and smooth in the micro-area and contained the highest level of Al2O3 (9.9 wt%). Diffraction peaks of the Ni grains in all Ni–Al2O3 TNCs appeared at 44.65°, 52.20°, 76.85°, and 92.55° assigned to the (1 1 1), (2 0 0), (2 2 0), and (3 1 1) planes, respectively, and corresponded to a face-centered cubic structure. The microhardness values of the Ni–Al2O3 TNCs initially increased before decreasing slightly as the ultrasonic power increased from 100 to 400 W. The NA-3 TNC had the highest microhardness (~ 916.2 Hv) among the Ni-Al2O3 TNCs tested. Furthermore, the NA-3 TNC processed the lowest corrosion current density (0.034 µA/mm2) and the highest maximum corrosion resistance. The average wear rate for the NA-3 TNC was only 26.1 mg/min. [ABSTRACT FROM AUTHOR]

Published

2022

43. Impact of ultrasonic power on liquid fraction, microstructure and physical characteristics of A356 alloy molded through cooling slope.

Author

Mohapatra, Pabak and Kund, Nirmal Kumar

Abstract

Copyright of Journal of Central South University is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

44. Characteristic Strength and Energy Evolution Law of Coal Treated by Ultrasonic Wave with Different Power Under Uniaxial Compression.

Author

Yang, Erhao, Lin, Haifei, Li, Shugang, Zhao, Pengxiang, Qin, Lei, Wang, Ruizhe, and Han, Shuangze

Subjects

ULTRASONIC waves, OCEAN wave power, COAL, COALBED methane, LONGITUDINAL waves, COAL combustion, ENERGY storage, ULTRASONIC testing

Abstract

Improving fissuring structures of low-permeability coal seams is crucial for enhancing coalbed methane (CBM) recovery. In this study, coal samples were treated with ultrasonic power of 264, 374, 484, 594, and 704 W, and the longitudinal wave velocity and micro-cracks of the coal samples were measured by ultrasonic testing and optical microscope before and after ultrasonic treatment. Moreover, the characteristic strength and final failure states of the samples were obtained during the uniaxial compression test. Furthermore, the intrinsic connection among mechanical properties, energy evolution, and micro-crack development was established and discussed, whereby the mechanism of the cracking coal bodies by ultrasonic excitation was explained. With increase in ultrasonic power, the micro-cracks propagation rate and the P-wave velocity decay rate increased synchronously. The strength and energy of ultrasonic-treated coal samples decreased significantly and the degree of compression failure was higher. Particularly, compared with the untreated specimens, the uniaxial compression strength decreased by 77.7%, and the fractal dimension of the end-state increased by 25.9% when the power was 704 W. The energy stored during the post-peak region of the specimens decreased with ultrasonic power increase; meanwhile, the energy required for macroscopic fracture extension decreased. Correspondingly, characterization parameters of limiting energy storage decreased from 5.1 to 87.8% and dissipation energy conversion rate decreased from 7.2 to 96.3%. Ultimately, ultrasonic power can effectively fracture the coal body, reduce its strength and energy storage capacity, and improve the permeability of the coal seam. [ABSTRACT FROM AUTHOR]

Published

2022

45. Comparative Study on the Effect of Ultrasonic Power on the Microstructure and Mechanical Properties of 2195 Aluminum Alloy Ingot

Author

Yuqi Hu, Ripeng Jiang, and Xiaoqian Li

Subjects

high-intensity ultrasound, 2195 aluminum–lithium alloy, ultrasonic power, the mechanical properties, precipitation phase, Technology

Abstract

High-intensity ultrasound was introduced for the casting of 2195 aluminum–lithium alloy ingots. The shape of the ingots was a cylinder with a length of 650 mm and a radius of 30 mm. In this study, the effects of different ultrasonic powers were applied in the melt. The grain shape, α-Al grain size, the size of the precipitated phase, and the mechanical properties of the ingots were compared. The results showed that when the power of the ultrasonic system was maintained at 1,600 W, an ingot with a more uniformly dispersed precipitation phase and grain refinement structure was formed. It can be concluded that the coarse eutectic structure in the ingot is effectively reduced when the power is around 1,600 W, and the mechanical properties of the ingot reach the best value.

Published

2022

46. Frequency and power dependence of ultrasonic degassing

Author

Yoshiyuki Asakura and Keiji Yasuda

Subjects

Ultrasonic degassing, Ultrasonic power, Ultrasonic frequency, Quenching, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

We investigated the time variation of ultrasonic degassing for air-saturated water and degassed water with a sample volume of 100 mL at frequencies of 22, 43, 129, 209, 305, 400, 514, 1018, and 1960 kHz and ultrasonic power of 15 W. Ultrasonic degassing was evaluated by dissolved oxygen concentration. Ultrasonic degassing was also investigated at a frequency of 1018 kHz and ultrasonic powers of 5, 10, 15, and 20 W. The dissolved oxygen concentration varied with the ultrasonic irradiation time and became constant after prolonged ultrasonic irradiation. The constant dissolved oxygen concentration value depended on the frequency and ultrasonic power but not the initial dissolved oxygen concentration. The degassing rate at 101.3 kPa was higher in the frequency range of 200 kHz to 1 MHz. The frequency dependence of the degassing rate was almost the same as that of the sonochemical efficiency obtained by the potassium iodide (KI) method. Ultrasonic degassing in the frequency range of 22–1960 kHz was also investigated under reduced pressure of 5 kPa. Degassing was accelerated when ultrasonic irradiation was applied under reduced pressure. However, under a reduced pressure of 5 kPa, the lower the frequencies, the higher is the degassing rate. The sonochemical reaction rate was examined by the KI method for varying dissolved air concentrations before ultrasonic irradiation. Cavitation did not occur when the initial dissolved oxygen concentration was less than 2 mg·L−1. Therefore, the lower limit of ultrasonic degassing under 101.3 kPa equals 2 mg·L−1 dissolved oxygen concentration. A model equation for the time variation of dissolved oxygen concentration due to ultrasonic irradiation was developed, and the degassing mechanism was discussed.

Published

2022

47. A novel ultrasound‐assisted vacuum drying technique for improving drying efficiency and physicochemical properties of Schisandra chinensis extract powder.

Author

Wang, Xuecheng, Xu, Shijun, Wu, Zhicheng, Li, Yuanhui, Wang, Yaqi, Wu, Zhenfeng, Zhu, Genhua, and Yang, Ming

Subjects

*SCHISANDRA chinensis, *WEIBULL distribution, *POWDERS, *FRUIT drying, *DRIED fruit, *THERMAL diffusivity

Abstract

Schisandra chinensis (S. chinensis) extract powder is an important intermediate for the preparation of many prepared medicines and health products. The physicochemical properties of S. chinensis extract powder have been found to vary tremendously and this has been attributed to the long drying time in the traditional drying method. In this study, S. chinensis specimens were authenticated as the dry fruit of S. chinensis (Turcz.) Baill. S. chinensis were extracted twice with 8 L kg−1 (liquid to solid ratio) distilled water. The extracts were mixed and concentrated under reduced pressure to 1.24 g cm−3. Ultrasound‐assisted vacuum drying (UAVD) was employed as a new approach to improve the efficiency in drying S. chinensis extract powder and produce a higher quality product. The effects of drying temperature (70, 80, 90°C), ultrasonic power (40, 120, 200 W), and ultrasonic application time (4, 12, 20 min every 20 min) on the kinetics and quality of S. chinensis extract were investigated and compared with the conventional vacuum drying (CVD). It was shown that, with the increase in drying temperature, ultrasonic power, and time of UAVD, the drying time for S. chinensis extract to reach the equilibrium moisture decreased. The drying time was reduced by more than 25% when utilizing UAVD compared to the CVD method. The effective moisture diffusivity (Deff) values for CVD and UAVD were 3.48 × 10–9 m2·s–1 and 7.41 × 10–9 m2 s–1, respectively, at the drying temperature of 80°C, indicating an increase of 112.93%. It was also found that a Weibull distribution model was suitable for predicting the moisture content of S. chinensis extract (R2 > 0.95). Furthermore, the content of Schisandrol A in the extracts obtained from UAVD was 12.79% higher than that obtained using CVD at 90°C. This demonstrates that UAVD is an efficient drying technique for S. chinensis extract. [ABSTRACT FROM AUTHOR]

Published

2022

48. JİPS ARTIĞINDAN TAGUCHİ YAKLAŞIMI KULLANILARAK ÇÖKTÜRÜLMÜŞ KALSİYUM KARBONAT (ÇKK) ÜRETİMİ.

Author

TOP, Soner, ALTINER, Mahmut, and KAYMAKOĞLU, Burçin

Abstract

Copyright of Journal of Engineering & Architectural Faculty of Eskisehir Osmangazi University / Eskişehir Osmangazi Üniversitesi Mühendislik ve Mimarlık Fakültesi Dergisi is the property of Eskisehir Osmangazi University and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

49. Frequency and power dependence of the sonochemical reaction

Author

Yoshiyuki Asakura and Keiji Yasuda

Subjects

Reaction rate, Ultrasonic power, Ultrasonic frequency, Quenching, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

The dependence of the sonochemical reaction on ultrasonic intensity was studied over a wide frequency range of 22–1960 kHz and sample volume range of 25–200 mL. The effect of a stainless steel reflector set on the water surface was also considered. Experiments were carried out by direct ultrasonic irradiation of a sample in a vessel. The potassium iodide (KI) method was used to evaluate the sonochemical reaction in terms of efficiency and reaction rate, and calorimetry was used to determine ultrasonic power. A quenching phenomenon, where the reaction rate decreased despite an increasing ultrasonic power, was observed at all frequencies and sample volumes, which indicated the existence of a maximum reaction rate. The maximum reaction rate increased with the frequency, except at 1960 kHz, and with the sample volume. The ultrasonic power at which quenching occurred increased with the frequency and sample volume. Sudden quenching occurred without the reflector, whereas gradual quenching occurred with the reflector. Based on the results, ultrasonic power density (i.e., ultrasonic power divided by the sample volume) can be used to estimate the ultrasonic power at which quenching occurs for various sample volumes.

Published

2021

50. Effect of ultrasonic pretreatment on the emulsification properties of Clanis Bilineata Tingtauica Mell protein

Author

Shuya Wang, Bin Zhou, Yingbin Shen, Yulin Wang, Yao Peng, Liqiong Niu, Xinquan Yang, and Shugang Li

Subjects

Clanis Bilineata Tingtauica Mell Protein (CBTMP), Ultrasonic power, Emulsification stability, Interfacial and rheological properties, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

Clanis Bilineata Tingtauica Mell Protein (CBTMP) is a naturally high-quality insect protein resource, while its poor emulsification has limited its application in food industry. In order to change the present situation, in this research, the ultrasonic pretreatment (0 W, 200 W, 400 W, 600 W, and 800 W) method was used to improve the emulsification properties of CBTMP. Results indicated that ultrasound treatment especially at 400 W could significantly change the particle sizes, further increase the content of sulfhydryl group and surface hydrophobicity. The emulsification properties of emulsions were enhanced (from 4.16 ± 1.07 m2/g to 27.62 ± 2.20 m2/g) by sonicated CBTMP solution. Moreover, the physical stability of the emulsions to salt stress and centrifugation treatment was also promoted. Additionally, rheology revealed that a stronger network was formed at 400 W and all samples exhibited frequency-dependent and amplitude-dependent properties. The experiment demonstrated that ultrasound pretreatment was an effective means to improve the emulsification properties of CBTMP and it could provide a promising perspective for the application of CBTMP in food industry.

Published

2021