Volume 47,Issue 6,2024 Table of Contents

1 Adsorption mechanism of fluorion removal from water by structure and valence-regulated Ce-MOFs and their derivatives

QU Min , HE Jiaojie , YANG Yixing , PEI Conghong , YANG Yue , ZHAO Hongmei , SUN Yan , YANG Liwei

2024, 47(6):1-14. DOI: 10.11835/j.issn.1000-582X-2024-06-001

[Abstract](218) [HTML](46) [PDF 4.26 M](390)

Abstract:
Controlling the concentration of fluorion in drinking water is crucial for reducing the risk of bone and dental fluorosis. In recent years, cerium-based adsorption materials, particularly cerium organic framework materials (Ce-MOFs) and their derivatives, have emerged as effective solutions for fluorion pollution. In this study, Ce-MOFs, namely CeT1 and CeT2 were synthesized using ammonium cerium nitrate (Ce(NH₄)₂(NO₃)₆) and homophenic acid (H₃BTC) at different reaction times, while CeD1 and CeD2 were generated by replacing H₃BTC with terephthalic acid (H₂BDC). Structural, surface area, elemental content and constituent group analyses were conducted using XRD, BET, SEM, XPS and FTIR techniques. Adsorption properties of the four materials were studied by controlling adsorption parameters, such as time, initial solute concentration, pH, and competing ions. Kinetic and isothermal models were employed to explore the adsorption mechanism. Characterization showed CeT1 as Ce(Ⅳ)-MOFs with high coordination unsaturation, CeD1 as Ce(Ⅳ)-MOFs with the largest specific surface area (1 003.10 m²/g), and CeT2 and CeD2 as Ce(Ⅲ) adsorption materials. Maximum adsorption capacities for CeT1, CeT2, CeD1 and CeD2 were determined as 99.38 mg/g, 142.45 mg/g, 60.45 mg/g and 124.55 mg/g, respectively. CeT1, CeT2 and CeD2 conformed to the pseudo-second-order kinetic model, while CeD1 conformed to the pseudo-first-order kinetic model. Adsorption mechanisms of fluorion in the four materials involved electrostatic attraction, ion exchange and precipitation, with CeT1 providing adsorption sites for ion exchange and electrostatic attraction due to unsaturated coordination. CeD1’s large specific surface area increases collision probability between pollutants and materials, while Ce(Ⅲ) in CeT2 and CeD2 facilitated precipitation by forming CeF₃ (K_sp=8×10^-16) with minimal solubility product constant. The study provides insights into the characteristics and defluorination abilities of Ce-MOFs and their derivatives, offering valuable reference for their preparation and optimization.

2 Research on temperature effect of concrete ultrasonic testing based on vector residual SVD

ZHENG Gang , CHEN Peng , PENG Yu , YU Jigang , CHEN Weiji

2024, 47(6):15-23. DOI: 10.11835/j.issn.1000.582X.2024.06.002

[Abstract](128) [HTML](30) [PDF 2.75 M](324)

Abstract:
In order to study the influence of temperature on the coda wave signal of concrete ultrasonic test, the normalized angle between signal vectors is used as the fluctuation index to reflect the signal change caused by temperature effect. The eigenvectors characterising the magnitude of the temperature effect are obtained by SVD of the vector residual matrix, and the mathematical relationship between the vector space mapping and the temperature difference is established. Verification of concrete beam code wave signals are collected in the laboratory. The results show that the waveform of the coda wave signal shifts backward with increasing temperature, and the proposed method can quantify the temperature effect piecewise and linearly. Based on the quantization results, the most sensitive temperature range of ultrasonic coda wave signal at room temperature is obtained. When the temperature span is 4.5 ℃, 74%~90% of the temperature effect can be removed.

3 Experimental research on development of low skirted friction suction caissons and its penetrability

LIU Xiaoke , SU Min , LU Qun , LIU Haitao , ZHAO Lihong , GUO Shaolong , WANG Qinghua

2024, 47(6):24-34. DOI: 10.11835/j.issn.1000-582X.2024.06.003

[Abstract](113) [HTML](26) [PDF 2.67 M](310)

Abstract:
In this study, a low skirted friction type suction caisson model was proposed to optimize suction foundation, reduce soil plugging effect, and improve penetrability and load capacity. Indoor model tests were conducted to investigate the relationship between penetration force, resistance and volume in negative pressure (P)-sinker volume (y) curves with different suction caisson types. Furthermore, the study analyzed differences among various caisson models and confirmed their penetrability and sinker volume. Results demonstrate that the low-skirt friction type suction caisson, offering improved penetrability, effectively mitigates soil plugging and improves caisson bearing capacity.

4 Effect of carbonation on the properties of granite-bearing oxysulfate oxide cement

JIN Kairong , ZHANG Xiaojing , BI Wanli , WANG Dezhi , HAN Jingyun

2024, 47(6):35-42. DOI: 10.11835/j.issn.1000-582X.2023.264

[Abstract](146) [HTML](34) [PDF 2.45 M](380)

Abstract:
The properties of magnesium oxysulfate (MOS) cement with different granite powder (GP) contents with CO₂curing were studied. The hydration products and microstructure of MOS cement were analyzed using X-ray diffraction (XRD), simultaneous comprehensive thermal analyzer (TG-DSC), scanning electron microscope (SEM) and mercury porosimeter (MIP). The results shows that the strength retention coefficient of MOS cement containing 40% GP reached 1.12 with standard curing for 28 days followed by 28 days of CO₂ curing; when MOS cement was CO₂-cured for 28 days and then immersed in water for 120 days, the strength retention coefficient reached 0.94, which was 123.8% higher than that of blank samples. MgCO₃·zH₂O crystals were generated after MOS cement underwent CO₂ curing, which had a positive effect on the mechanical properties and water resistance by reducing matrix expansion caused by MgO hydrating to Mg(OH)₂. GP increased the matrix density, reduced the CO₂ capture rate, and decreased CO₂ erosion of MOS cement by optimizing the pore structure. The presence of GP and magnesium carbonate phases improved the compressive strength of MOS cement after carbonation and immersion.

5 Influence of phyllite aspect ratio under static and dynamic compression

XU Jiangbo , YU Yanglin , SUN Guozheng , SUN Haohui , LAI Jie , WANG Lei

2024, 47(6):43-57. DOI: 10.11835/j.issn.1000.582X.2024.06.005

[Abstract](111) [HTML](30) [PDF 4.98 M](352)

Abstract:
This study investigates the influence of aspect ratio on the mechanical properties, energy dissipation, and failure mode of layered phyllite. Uniaxial compression and split Hopkinson pressure bar (SHPB) tests were conducted on phyllite specimens with varying aspect ratios (L/D=0.5,0.6,0.8,1.0,1.2,1.6,2.0) at four inclination angles(α=0°，30°，60°，90°). Results from static uniaxial compression test reveal that the peak strength and the peak strain of phyllite decrease with increasing aspect ratio at different dip angles. Uniaxial dynamic compression tests show that the dynamic compressive strength of phyllite with four bedding dip angles exhibits a quadratic function relationship with the length-diameter ratio of the specimen under dynamic impact compression conditions. With increasing length-diameter ratio, the dynamic compressive strength reaches a peak and then gradually decreases. The peak strain of phyllite decreases exponentially with the aspect ratio of specimen. Energy analysis of dynamic impact compression test indicates a three-stage change in incident energy, reflection energy, and transmission energy of phyllite under different working conditions, from slow rise to rapid rise and finally to being stable. The reflection energy ratio of phyllite increases first and then decreases with the increase of the length-diameter ratio, while the transmission energy ratio shows the opposite trend. Comparative analysis using the energy ratio method reveals that the reflection energy ratio of phyllite reaches its maximum and the transmission energy ratio reaches its minimum when the aspect ratio is L/D=1.2. Macroscopic failure mode analysis indicates that the aspect ratio significantly affects the macroscopic failure mode of phyllite under dynamic impact compression, with smaller the aspect ratios resulting in more complete fractures and larger aspect ratios leading to less sufficient damage.

6 Experimental study on axial compressive performance of assembled square pier with tenon and mortar sleeve hybrid connection

LIN Shangshun , HE Yue , XIA Zhanghua , QIN Zhiqing , ZHANG Letong , CHEN Zhixiong

2024, 47(6):58-67. DOI: 10.11835/j.issn.1000.582X.2024.06.006

[Abstract](102) [HTML](28) [PDF 3.52 M](435)

Abstract:
Existing studies have shown that the seismic performance of the mortise and grouting sleeve mixed connection assembled square pier (referred to as the mixed connection assembled pier) is close to that of the integral cast-in-place pier. In order to further explore the axial compression performance of the mixed-connected bridge piers, a series of axial compressive tests were conducted on one integral cast-in-place bridge pier (No. ZT) and four mixed connection and assembled bridge piers (No. GTA-0~GTD-0) with varying parameters such as the length, diameter and wall thickness of the steel pipes. The results show that the bearing capacity of GTA-0~GTD-0 specimens increased by 10.1% to 14.4% compared to the ZT specimens, and their ductility coefficients were all greater than that of ZT specimens. The axial compression bearing capacity of GTA-0~GTD-0 specimens increased with the diameter and length of the steel pipe, while the wall thickness of the steel pipe had a relatively minor impact on the bearing capacity. The damage position of the assembled bridge pier moves upward with the increase of the steel pipe length, gradually approaching the integral cast-in-place bridge pier, but the failure modes of the two are basically the same.

7 Experimental study on thermomechanical behaviour of clay under different curing conditions

XIAO Yongjie

2024, 47(6):68-74. DOI: 10.11835/j.issn.1000.582X.2024.06.007

[Abstract](109) [HTML](32) [PDF 1.32 M](307)

Abstract:
The physical and mechanical properties of soil are greatly influenced by temperature. Triaxial tests under different curing conditions were carried out on clay to investigate its thermomechanical behavior. This paper presents the findings of a laboratory investigation into the thermomechanical behavior of clay. Experimental results show that clay exhibits thermal consolidation properties. As temperature increases, the consolidation speed of clay accelerates, and the consolidation time shows a decreasing trend. Below the critical temperature, the stress-strain curve of the soil presents softening characteristics and brittle failure. Above the critical temperature, the stress-strain curve shows hardening characteristics and plastic failure. Clay exhibits a behavior similar to the “curing temperature” of concrete, where a longer curing time results in a greater principal stress difference. Within the critical temperature range, cohesion decreases with increasing temperature, while above the critical temperature, cohesion increases with temperature. Within the critical temperature range, the internal friction remains unaffected by temperature changes. However, above the critical temperature, the internal friction increases with temperature. The strength development of clay with curing time is divided into rapid growth, followed by a stage of less rapid growth and slow growth. The optimal curing time occurs during these rapid growth stages.

8 A novel red-black coloring parallel projection algorithm for two-phase flow using the phase field method

WANG Xiaoshuang , ZHANG Liangqi , XIAO Yao , ZENG Zhong

2024, 47(6):75-85. DOI: 10.11835/j.issn.1000-582X.2023.259

[Abstract](158) [HTML](33) [PDF 2.93 M](290)

Abstract:
In this study, an innovative parallel finite volume projection algorithm with a novel red-black coloring approach is proposed to solve the two-phase flow control equations using the phase field method. This strategy relies on the explicit advancement of the pressure Poisson equation, thus effectively overcoming the efficiency limitation inherent in the traditional projection algorithms for solving the incompressible Navier-Stokes equations. Moreover, we implement an interleaved scanning strategy for updating nodal variables, which significantly enhances the spatiotemporal coupling in a compact manner. The integration of this technique with the phase field method facilitates more accurate capture of interface dynamics and topology at a lower cost. Test results show that, utilizing a grid size of 131 072 and an 8-thread CPU parallelization, the proposed parallel algorithm is more than 80 times more efficient than the serial standard projection algorithm.

9 Malware incremental training and detection method based on neural network smooth aggregation mechanism

GUO Zhimin , CHEN Cen , LI Nuannuan , CAI Junfei , ZHANG Zheng

2024, 47(6):86-93. DOI: 10.11835/j.issn.1000.582X.2024.06.009

[Abstract](136) [HTML](29) [PDF 1.35 M](314)

Abstract:
To ensure the timeliness of malware variant detection models, traditional machine (deep) learning-based detection methods integrate historical and incremental data and retrain to update detection models. However, this approach often suffers from low training efficiency. Therefore, this paper proposes an incremental learning method based on a neural network smooth aggregation mechanism for detecting malware variants, facilitating the smooth evolution of detection models. The method introduces a training scale factor to prevent the decrement of accuracy in the aggregated incremental model due to small training scales. Experimental results show that the proposed incremental learning method can improve training efficiency while maintaining the accuracy of the detection model compared to the re-training method.

10 Optimization design of four-coil mid-range wireless power transfer based on E-class amplifier

LIU Yu , YU Haohua , PENG Bo , SU Guodong

2024, 47(6):94-102. DOI: 10.11835/j.issn.1000.582X.2024.06.010

[Abstract](100) [HTML](24) [PDF 2.21 M](370)

Abstract:
The E-class power amplifier presents an ideal solution for high-frequency power supply applications, characterized by its simple topology, high operational frequency, and efficiency. This paper conducts a detailed analysis of the transfer characteristics of a four-coil wireless power transfer(WPT) system and proposes an optimal design method to achieve high transfer efficiency. Additionally, with considering the operating status of the E-class amplifier, perfect matching of input resistance is achieved by adjusting the distance between the driving coil and transmitting coil. A 2.81 MHz four-coil mid-range WPT system employing an E-class amplifier is established. At a transfer distance of 3.6 times the side length of the transfer coil, the overall transfer efficiency from the power source to the load reaches 8.5%.

11 Dynamic performance optimization method of WPT system based on controllable inductor

LING Rongguang , HE Leijie , LIU Qiao , MENG Fanchao , YE Jiaqing , TANG Chunsen

2024, 47(6):103-117. DOI: 10.11835/j.issn.1000.582X.2024.06.011

[Abstract](108) [HTML](29) [PDF 2.67 M](379)

Abstract:
The SS Buck-WPT system, comprised of a buck converter and a basic SS-type wireless power transfer circuit, has gained widespread adoption in inductive wireless power transmission due to its structural superiority, control methods, and effectiveness. However, this system fails to meet the responsiveness requirements of time-varying systems due to its poor dynamic characteristics. In practical applications, it exhibits significant overshoot and oscillation during startup, instability when subjected to varying load resistances, and sharp fluctuations in primary resonance current under light conditions. To address those dynamic challenges, this paper proposes a SS-type Buck-WPT system based on controllable inductance. Firstly, controllable inductance was thoroughly analyzed to understand the principle of adjustable inductance, and then modeled in COMSOL to verify the findings. Mathematical modeling analysis of the SS Buck-WPT system was conducted, with the system state space equation derived by considering the SS WPT system as the load of the buck converter. The system was described using two-dimensional phase trajectories to simplify the analysis. A phase trajectory operation law during start-up was proposed, and the pre-buck circuit was improved by replacing the conventional inductor with a controllable one, allowing for stable operation with minimal overshoot during startup. The PI algorithm was used to maintain constant current despite load changes, ensuring expected phase trajectory behavior and rapid return to steady-state operation with real-time control of inductance. Excessive primary resonant current was mitigated by cascading the controlled inductance with the SS in the primary circuit, adjusting the inductance automatically to keep current within permissible values. To validate the proposed method, a prototype was implemented in Simulink. Results show that this strategy significantly improves system dynamic performance and tolerance to varying loads compared to traditional methods.

12 Anti-deflection and interoperability study of WPT based on distributed transmitting coils

SHEN Tao , SU Dong , WU Zhanli , DONG Jinxi , LIU Xiliu , WANG Bo

2024, 47(6):118-136. DOI: 10.11835/j.issn.1000.582X.2024.06.012

[Abstract](122) [HTML](36) [PDF 6.12 M](402)

Abstract:
The offset in the relative position between the receiver and the transmitter in a radio energy transmission system can significantly impact transmission efficiency. We investigate the full-range offset resistance and the interoperability of the coupling mechanism, and propose a novel many-to-one coupling mode. By utilizing planar distributed transmit unit coil combination and studying the open mode of the distributed transmit coil with various receive coil types, axial offset conditions and rotational offset conditions, the interoperability and wide-range all-directional offset resistance of the receive coil is achieved. To improve the degree of freedom of the distributed transmit coil, a distributed series control logic circuit is proposed, and the resonance parameters of the transmit coil are designed for series connection condition to reduce cross-coupling effect. A search strategy for receiving coil position detection is proposed by combining the magnetic field characteristics of the distributed transmit coil with a pickup voltage detection method based on the LCC-S resonant topology. An experimental setup is constructed with considering axial and rotational offsets in all positions. The maximum efficiency fluctuation of the planar receiving coil is found to be 3.3%, the maximum for the vertical receiving coil is 5.57%, and for the solenoid receiving coil is 4.45%. Experimental results show that the proposed system exhibits good anti-offset characteristics and interoperability, verifying the feasibility and efficiency of the system.

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