Application of Artificial Ground Freezing Technology in Modern Urban Underground Engineering

Qi, Yinghua; Jinxun, Zhang; Yang, Hao; Song, Yongwei

doi:10.1155/2020/1619721

Cited by 10 publications

(6 citation statements)

References 2 publications

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“…In contrast to the relatively sparse amount of studies concerning artificial ground thawing, there is an abundance of studies and mathematical models covering frost action and artificial ground freezing, that is, the reverse process (Alzoubi et al 2017;Blanchard and Fremond 1985;Bronfenbrener 2009;Bronfenbrener and Bronfenbrener 2010;Brown and Payne 1990;Mackay et al 1992;Naaktgeboren 2006;Nixon 1990;Qi et al 2020;Rouabhi et al 2018;Yan et al 2019;Yokoo et al 2005;Zhou et al 2009Zhou et al , 2021. However, many such models cannot be directly applied for accurately predicting thaw depth.…”

Section: Prediction Modelsmentioning

confidence: 99%

Artificial Thawing of Frozen Ground: A Review

2022

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Understanding the freezing and thawing processes in porous media such as soils is important, especially in regions experiencing seasonal frost or permafrost. These processes have a wide range of implications as diverse as how to maintain the structural integrity of roads, railways, pipelines, and buildings, to when to plant seeds during the growth season. Thawing of frozen ground is the opposite process of ground freezing but has not received nearly as much attention as the latter in research studies or field experiments. Accurately predicting thaw depth or thaw rate is a challenging task. Many mathematical models have been proposed to describe the thawing process, with different perspectives and complexity. This paper provides an overview of historical modeling efforts made for predicting heat and mass transfer during thawing. Assumptions and premises for each model are discussed, as well as limitations and some applications. In addition, this paper reviews historical and modern approaches to thawing of frozen ground in cold regions, lists pros and cons of each method, and gives examples of applications. The review shows the need for further research and more accurate models, specifically for predicting thaw depth and thaw rates in frozen ground subjected to artificial thawing.

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Section: Prediction Modelsmentioning

confidence: 99%

Artificial Thawing of Frozen Ground: A Review

2022

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“…Artificial freezing technology was proposed by a German engineer in the 1860s and was initially applied in mine excavation for mining coal [ 1 , 2 ]. It has been widely used abroad due to its advantages of safety, flexibility and efficiency [ 3 ]. Since the 20th century, many countries have used artificial ground freezing technology in engineering fields such as subways, tunnels and coal mines, and have accumulated a lot of experience [ 4 – 8 ].…”

Section: Introductionmentioning

confidence: 99%

Numerical simulation of temperature field of a new type of freezing device under seepage effect

Yang,

Wang,

Ren

2024

PLoS ONE

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In order to investigate the development of the temperature field of a new type of freezing reinforcement under seepage conditions, in this paper, COMSOL finite element software was used to simplify the model and simulate the effect of groundwater seepage on the development of the temperature field of frozen pipes by coupling the Darcy’s law module and the heat transfer module for porous media. The heads of water were also varied to simulate the change in seepage velocity to further investigate the effect of seepage velocity on the temperature field. The results of the study show that the freezing wall formed in the high head region was thinner than that in the low head region due to the effect of seepage, and this phenomenon was aggravated with the increase of seepage rate; The effect of seepage action on the temperature field had a hysteresis along the seepage direction; When the seepage rate was greater than 1.65 m/d, the soil in the center of the device feezed better and could form a tight and dense freezing wall comparable to the size of the freezing device; When the seepage rate was greater than 5.78 m/d, the temperature of the center soil body gradually increased, and eventually the freezing curtain cannot be formed.

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“…Four mainstream methods can be used to study these problems; they are theoretical analysis, numerical simulation, model test, and field monitoring. Qi et al [15] studied the temperature field expansion of basinshaped freezing method through physical model test and numerical simulation; it shows the gradual development of freezing from backwater surface to front water surface under seepage condition. Liu et al [16] studied the freezing effect considering the pipe inclination in the unit cell model by prescribing various values of freeze pipe spacing based on a coupled thermohydraulic finite element method.…”

Section: Introductionmentioning

confidence: 99%

Model Test and Numerical Simulation Analysis on Freezing Effect of Different Freezers in Freeze-Sealing Pipe-Roof Method

et al. 2022

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The Gongbei Tunnel Project is a key phased project of the Zhuhai Connection Line of the Hong Kong–Zhuhai–Macao Bridge, and the freeze-sealing pipe-roof (SFPR) method was first applied successfully. During this period, in order to obtain the best arrangement of freezers, three configurations, that is, solid pipe with circular freezer (SCF), empty pipe with double circular freezer (EDCF), and empty pipe with special-shaped freezer (ESF), were designed to analyze their freezing effects. The model test results show that the freezing temperature fields excited by different arrangements of freezers are obviously different, and the freezing effect of ESF is the best. The numerical simulation results indicate that the temperature cloud diagram of SCF at 42 h is butterfly-shaped after opening the limit pipes, and the temperature cloud diagrams of ESF and EDCF are the same as the model test results. However, the processing method of ESF is relatively complex, which adopts arc angle steel welding requiring a lot of reverse welding and high welding quality. Eventually, EDCF is recommended to ensure the quality of frozen walls due to its lower cost and better freezing effect. This research plays a basic role in the implementation of the freeze-sealing pipe-roof method.

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Application of Artificial Ground Freezing Technology in Modern Urban Underground Engineering

Cited by 10 publications

References 2 publications

Artificial Thawing of Frozen Ground: A Review

Artificial Thawing of Frozen Ground: A Review

Numerical simulation of temperature field of a new type of freezing device under seepage effect

Model Test and Numerical Simulation Analysis on Freezing Effect of Different Freezers in Freeze-Sealing Pipe-Roof Method

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