基于冻土热传导方程解析解的相似准则研究

doi:10.11988/ckyyb.20240191

raybet体育在线院报 ›› 2025, Vol. 42 ›› Issue (5): 184-191.DOI: 10.11988/ckyyb.20240191

基于冻土热传导方程解析解的相似准则研究

伯音¹^,²^,³(), 王聪¹^,², 冯彦芳³, 张彬⁴, 张莹⁴, 郭晓刚¹^,², 姚劲松¹^,², 魏莱¹^,², 陈荣¹^,², 徐琛⁵

¹ 长江设计集团有限公司, 武汉 430010
² 水利部水网工程与调度重点实验室, 武汉 430010
³ 武汉大学土木建筑工程学院,武汉 430072
⁴ 十堰市城市水源有限责任公司, 湖北十堰 442012
⁵ 武汉理工大学资源与环境工程学院, 武汉 430070

收稿日期:2024-03-01 修回日期:2024-05-29 出版日期:2025-05-01 发布日期:2025-05-01
作者简介:
伯音(1995-)男,蒙古族,吉林松原人,工程师,博士,主要从事TBM隧道施工研究。E-mail:boyin@cjwsjy.com.cn
基金资助:
湖北省青年基金项目(2024AFB518); 湖北省青年基金项目(2022CFB673)

Similarity Criterion Based on the Analytical Solution of Heat Conduction Equation in Frozen Soil

BO Yin¹^,²^,³(), WANG Cong¹^,², FENG Yan-fang³, ZHANG Bin⁴, ZHANG Ying⁴, GUO Xiao-gang¹^,², YAO Jin-song¹^,², WEI Lai¹^,², CHEN Rong¹^,², XU Chen⁵

¹ CISPDR Corporation, Wuhan 430010, China
² Key Laboratory of Water Grid Project and Regulation ofMinistry of Water Resources, Wuhan 430010, China
³ School of Civil Engineering, Wuhan University, Wuhan430072, China
⁴ Shiyan Urban Water Source Co., Ltd., Shiyan 442012, China
⁵ School of Resource andEnvironmental Engineering,Wuhan University of Technology, Wuhan 430070, China

Received:2024-03-01 Revised:2024-05-29 Published:2025-05-01 Online:2025-05-01

摘要/Abstract

摘要：

为研究冻土一维热传导温度场模型试验相似准则,创新性提出基于微分方程解析解求取相似准则的方法,首先采用分离变量法得到了一维非线性热传导方程的解析解,再利用相似转换法推导出了考虑和不考虑热交换2种情况下冻土模型试验的相似准则,最后利用有限元软件ABAQUS验证相似准则的准确性。结果表明,当不考虑热交换时,时间的相似常系数始终是几何尺寸相似常系数的平方;当考虑热交换时,模型试验必须采用与原型不同的土体,此时得到的相似准则更具有理论意义和实际价值。该研究成果充分考虑了热传导过程中的边界条件,有望为非线性热传导问题的研究和模型试验设计提供理论参考。

关键词: 冻土, 非线性热传导, 解析解, 相似准则, 模型试验

Abstract:

[Objective] The evolution pattern of temperature field in frozen walls serves as a key factor in optimizing design schemes during artificial ground freezing. At present, laboratory model tests are a critical approach for investigating the development of temperature fields. This study aims to propose a method for deriving similarity criteria for temperature field model tests, offering essential theoretical guidance for the design of laboratory experiments. [Methods] First, analytical solutions to one-dimensional heat conduction differential equations, under both constant and nonlinear thermal parameters, were obtained using the method of separation of variables with different boundary conditions. Based on these solutions, similarity transformation techniques were employed to derive similarity criteria for frozen soil model tests, accounting for both heat exchange and non-heat-exchange conditions. Finally, the finite element software ABAQUS was utilized to conduct numerical simulations of the temperature fields for both prototype and model soils under constant and nonlinear thermal conductivity conditions, verifying the accuracy of the derived criteria. [Results] Results indicated that under non-heat-exchange conditions, when the first-type (Dirichlet) and second-type (Neumann) boundary conditions were combined, the time similarity coefficient equaled the square of the geometric similarity coefficient, enabling rapid determination of model test durations once the geometric scaling ratios were predefined. Similarly, under the combination of second-type and third-type (Robin) boundary conditions, the time similarity constant coefficient remained the square of the geometric similarity constant coefficient. This consistency held regardless of whether thermal parameters were constant or nonlinear, meaning that the time similarity coefficient was the square of the heat conduction geometric similarity coefficient. ensuring uniform criteria between prototype and model cases. When heat exchange was considered, the temperature similarity coefficient was no longer constant. In such cases, the test soil must be replaced and the similarity coefficients of thermal properties such as thermal conductivity, specific heat capacity, and density must satisfy specific quantitative relationships with those of the prototype soil. [Conclusion] The simulation results showed that under the corresponding time and geometric scaling conditions derived in this study, the temperature fields of the prototype and model closely matched, further validating the accuracy of the proposed similarity criteria. The similarity criteria derived from analytical solutions to heat conduction equations fully incorporate the effects of heat exchange boundary conditions and provide a fast and accurate method for determining scaling relationships when similarity coefficients for relevant thermophysical parameters are known. These findings are expected to offer a theoretical basis for solving nonlinear heat conduction problems and for guiding the design and execution of frozen soil model tests.

Key words: frozen soil, non-linear heat conduction, analytic solution, similarity criterion, model test

中图分类号:

TU752冻土施工、冻土工程

伯音, 王聪, 冯彦芳, 张彬, 张莹, 郭晓刚, 姚劲松, 魏莱, 陈荣, 徐琛. 基于冻土热传导方程解析解的相似准则研究[J]. raybet体育在线院报, 2025, 42(5): 184-191.

BO Yin, WANG Cong, FENG Yan-fang, ZHANG Bin, ZHANG Ying, GUO Xiao-gang, YAO Jin-song, WEI Lai, CHEN Rong, XU Chen. Similarity Criterion Based on the Analytical Solution of Heat Conduction Equation in Frozen Soil[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(5): 184-191.

模型	边界条件	模型编号
常系数原型	一二类边界	A1
常系数原型	一二类边界	A2
常系数原型	考虑热交换	A3
常系数原型	考虑热交换	A4
非线性原型	比热C非线性一二类边界	A5
非线性原型	比热C非线性一二类边界	A6
换土模型	考虑热交换	A7

模型	边界条件	模型编号
常系数原型	一二类边界	A1
常系数原型	一二类边界	A2
常系数原型	考虑热交换	A3
常系数原型	考虑热交换	A4
非线性原型	比热C非线性一二类边界	A5
非线性原型	比热C非线性一二类边界	A6
换土模型	考虑热交换	A7

土样	c_l	c_λ	c_C	c_T	c_α	c_A	c_B	c_t
原土	2	1	1	1	1	1	1	4
模型土	2	2	1/2	4	-	2	1	1/4

土样	c_l	c_λ	c_C	c_T	c_α	c_A	c_B	c_t
原土	2	1	1	1	1	1	1	4
模型土	2	2	1/2	4	-	2	1	1/4

模型编号	密度/ (kg·m^-3)	比热/ (J·(kg·℃)^-1)		导热系数/ (W·(m·℃)^-1)
A1、A2、 A3、A4	1.91×10³	1.95×10³		5.004×10³
A5、A6	1.91×10³	100T^-2		5.004×10³
A7	1.91×10³	200T^-2		2.502×10³
模型编号	初始温度/℃		冷源温度/℃		环境温度/℃
A1、A2、 A3、A4	0		-20		6.8
A5、A6	-0.330		-20		6.8
A7	-0.083		-5		6.8

基于冻土热传导方程解析解的相似准则研究

Similarity Criterion Based on the Analytical Solution of Heat Conduction Equation in Frozen Soil

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