The temperature prediction of the Clamp-conductor coupling zone plays a crucial role in ensuring the safe and stable operation of overhead transmission lines and optimizing the thermal stability margin of transmission...The temperature prediction of the Clamp-conductor coupling zone plays a crucial role in ensuring the safe and stable operation of overhead transmission lines and optimizing the thermal stability margin of transmission lines.While existing research in this field has thoroughly explored temperature rise prediction,the focus has been relatively narrow,either targeting conductors exclusively or focusing solely on clamps,with little attention given to the temperature rise in the conductor-clampcoupling zoneor the influenceof clamp temperatureonconductor temperature rise.Based on this,considering axial heat transfer between the clamp and the conductor,this study develops a thermal model to calculate temperature in the clamp-conductor interface zone.A Whale Optimization Algorithm(WOA)-based parameter identification method is employed to overcome challenges in determining model parameters.To validate model performance,a current-carrying temperature-rise experimental platform was designed to supply data for both model verification and parameter identification.By comparing the calculation results with the experimental data,the results show that the maximum average error does not exceed 1.4%,and the maximum error is only 2.79%,verifying the validity of the parameter identificationmethod and thermalmodel.Thiswork lays a theoretical foundation for predicting temperature distributions at clamp-conductor interfaces under realistic meteorological conditions and supports short-termdynamic capacity increases for overhead conductors,demonstrating significant practical relevance.展开更多
A series of Co-Sn alloys with Sn content ranging from 12% to 32%(mole fraction) were undercooled to different degrees below the equilibrium liquidus temperature and the solidification behaviors were investigated by ...A series of Co-Sn alloys with Sn content ranging from 12% to 32%(mole fraction) were undercooled to different degrees below the equilibrium liquidus temperature and the solidification behaviors were investigated by monitoring the temperature recalescence and examing the solidification microstructures.A boundary clearly exists,which separates the coupled growth zone from the decoupled growth zone of eutectic phases for the alloys with Sn content ranging from 14% to 31%(mole fraction).The other Co-Sn alloys out of this content range are hard to be undercooled into the coupled growth zone in the experiment.It is found that the so-called non-reciprocal nucleation phenomenon does not happen in the solidification of undercooled Co-Sn off-eutectic alloys.展开更多
A coupled system simulating both firebox and reactor is established to study the naphtha pyrolysis in an industrial tubular furnace.The firebox model is based on zone method including combustion,radiation,and convecti...A coupled system simulating both firebox and reactor is established to study the naphtha pyrolysis in an industrial tubular furnace.The firebox model is based on zone method including combustion,radiation,and convection to simulate heat transfer in the furnace.A two-dimensional recirculation model is proposed to estimate the flow field in furnace.The reactor model integrates the feedstock reconstruction model,an auto-generator of detail kinetic schemes,and the reactor simulation model to simulate the reaction process in the tubular coil.The coupled simulation result is compared with industrial process and shows agreement within short computation time.展开更多
Reverse-swirl(RS)burner which has been industrialized couples reverses jet and swirl flow for the stabilization of flame.Using Dantec multichannel constant-temperature anemometer,experiments on airflow characteristics...Reverse-swirl(RS)burner which has been industrialized couples reverses jet and swirl flow for the stabilization of flame.Using Dantec multichannel constant-temperature anemometer,experiments on airflow characteristics were implemented on a 1:2 scaled burner model with different values in terms of reverse primary air(RPA)ratio and swirl inner secondary air(SISA)ratio.It was found that the shape of annular coupled recirculation zone(ACRZ)had stayed symmetrical all the time.The RPA ratio was the main factor that had an impact on the values of axial and RMS velocity as well as the radial velocity direction of ACRZ.Both RPA ratio and SISA ratio had a great impact on the area of ACRZ,relative reverse flow rate,mixing between SISA and outer secondary air(OSA)as well as swirling ability of the airflow.The area of ACRZ reached its peak when the RPA ratio was 11.92%or SISA ratio was 17.03%;however,when the RPA ratio and SISA ratio reached 14.86%and 28.41%respectively,the combination of RPA and SISA became relatively favorable;besides,ACRZ area,relative reverse flow and swirling ability became suitable and the mixing between SISA and OSA was relatively delayed.The research was of great practical and theoretical importance to the design and operation of RS burner.展开更多
基金supported by the Technology Innovation Leading Program of Shaanxi(2024QCY-KXJ-009)the Research Plan of the EducationDepartment of Shaanxi Province(23JC028)+1 种基金supported by the National Key Laboratory of Metal Forming Technology and Heavy Equipment B2408100.W14.Key Research and Development Program of Shaanxi(2025CY-YBXM-489).
文摘The temperature prediction of the Clamp-conductor coupling zone plays a crucial role in ensuring the safe and stable operation of overhead transmission lines and optimizing the thermal stability margin of transmission lines.While existing research in this field has thoroughly explored temperature rise prediction,the focus has been relatively narrow,either targeting conductors exclusively or focusing solely on clamps,with little attention given to the temperature rise in the conductor-clampcoupling zoneor the influenceof clamp temperatureonconductor temperature rise.Based on this,considering axial heat transfer between the clamp and the conductor,this study develops a thermal model to calculate temperature in the clamp-conductor interface zone.A Whale Optimization Algorithm(WOA)-based parameter identification method is employed to overcome challenges in determining model parameters.To validate model performance,a current-carrying temperature-rise experimental platform was designed to supply data for both model verification and parameter identification.By comparing the calculation results with the experimental data,the results show that the maximum average error does not exceed 1.4%,and the maximum error is only 2.79%,verifying the validity of the parameter identificationmethod and thermalmodel.Thiswork lays a theoretical foundation for predicting temperature distributions at clamp-conductor interfaces under realistic meteorological conditions and supports short-termdynamic capacity increases for overhead conductors,demonstrating significant practical relevance.
基金Project(50874073) supported by the National Natural Science Foundation of ChinaProject(2011CB610405) supported by the National Basic Research Program of ChinaProject(2011M500074) supported by China Postdoctoral Science Foundation
文摘A series of Co-Sn alloys with Sn content ranging from 12% to 32%(mole fraction) were undercooled to different degrees below the equilibrium liquidus temperature and the solidification behaviors were investigated by monitoring the temperature recalescence and examing the solidification microstructures.A boundary clearly exists,which separates the coupled growth zone from the decoupled growth zone of eutectic phases for the alloys with Sn content ranging from 14% to 31%(mole fraction).The other Co-Sn alloys out of this content range are hard to be undercooled into the coupled growth zone in the experiment.It is found that the so-called non-reciprocal nucleation phenomenon does not happen in the solidification of undercooled Co-Sn off-eutectic alloys.
基金Supported by the National Natural Science Foundation of China(U1462206)
文摘A coupled system simulating both firebox and reactor is established to study the naphtha pyrolysis in an industrial tubular furnace.The firebox model is based on zone method including combustion,radiation,and convection to simulate heat transfer in the furnace.A two-dimensional recirculation model is proposed to estimate the flow field in furnace.The reactor model integrates the feedstock reconstruction model,an auto-generator of detail kinetic schemes,and the reactor simulation model to simulate the reaction process in the tubular coil.The coupled simulation result is compared with industrial process and shows agreement within short computation time.
基金China Coal Research Institute Company of Energy Conservation Project(No.11021-ZC)for the support to our research.
文摘Reverse-swirl(RS)burner which has been industrialized couples reverses jet and swirl flow for the stabilization of flame.Using Dantec multichannel constant-temperature anemometer,experiments on airflow characteristics were implemented on a 1:2 scaled burner model with different values in terms of reverse primary air(RPA)ratio and swirl inner secondary air(SISA)ratio.It was found that the shape of annular coupled recirculation zone(ACRZ)had stayed symmetrical all the time.The RPA ratio was the main factor that had an impact on the values of axial and RMS velocity as well as the radial velocity direction of ACRZ.Both RPA ratio and SISA ratio had a great impact on the area of ACRZ,relative reverse flow rate,mixing between SISA and outer secondary air(OSA)as well as swirling ability of the airflow.The area of ACRZ reached its peak when the RPA ratio was 11.92%or SISA ratio was 17.03%;however,when the RPA ratio and SISA ratio reached 14.86%and 28.41%respectively,the combination of RPA and SISA became relatively favorable;besides,ACRZ area,relative reverse flow and swirling ability became suitable and the mixing between SISA and OSA was relatively delayed.The research was of great practical and theoretical importance to the design and operation of RS burner.
