试论地球深部地热能传输机理

doi:10.13745/j.esf.2020.1.2

摘要/Abstract

摘要：

本文在对前人地热成因认识归纳检验的基础上,通过演绎推理的方法,从几条基本的物理定律和基本假设组成的第一性原理出发,推理“地球内部热能从深部向浅表传输”的动力学过程,探讨深层地热能热源机制。热源机制问题从物理学的角度看,本质上就是热能从地球内部向近地表传输的问题。可以根据第一性原理,通过演绎法推理其可能的传输过程。深层热能传输的第一性原理由“温度的定义、热胀冷缩原理、阿基米德原理、热力学第二定律以及辐射、传导和对流三种热量传输方式的效率对比”5条基本的概念和定理组成。结合地球已知的圈层结构,通过演绎推理可知,在固态内核偏移驱动下,液态外核开始流动,在局部聚集导致地幔中形成上升的地幔柱;地幔柱在另一个地球圈层界面发生顶托作用,使得界面上凸,并产生烘烤加热作用,被烘烤的上层物质流变性增强发生侧向流动,于是物质垂直运动转换为水平运动。水平流动的热物质聚集到一定程度又会上浮产生垂直运动。如此垂直运动和水平运动不断转换,最终将地球深部地核中的热能传输到了地壳浅层。地球深部热能向浅表传输的过程会导致海底增生扩张、板块运动、盆山耦合等,同时也形成不同级别的控热构造系统。地球尺度的控热构造系统为:地球内核为生热构造,液态外核为储热构造,各级地幔柱和流动的高温物质为导热构造,地表的火山、温泉、地震为释热构造子系统。大陆地壳准固态流变物质的侧向流动是干热岩形成的主控因子,对于干热岩地热能勘查具有重要意义。

关键词: 深层地热, 热传输机制, 演绎推理, 第一性原理, 干热岩

Abstract:

Based on deductive testing of previous mechanistic models of geothermal energy generation, we deduced the dynamic process of “internal heat transfer from the deep to the shallow surface of the earth”. We also discussed the mechanism of deep geothermal energy transmission from a few basic laws (first principles) through deductive reasoning. From a physical perspective, geothermal energy is essentially the result of thermal energy transfer from the Earth’s interior to the shallow crust. According to the first principle, the possible transmission process can be inferred by deductive method. The first principle of deep thermal energy transmission consists of five basic concepts: definition of temperature, principle of thermal expansion and contraction, Archimedes principle, thermal radiation and second law of thermodynamics and comparative efficiencies of three heat transfer modes of conduction and convection. Combined with the known Earth’s spherical structure, it can be seen from deductive reasoning that the liquid outer core begins to flow under the migration of the solid inner core, resulting in upwelling of mantle plume due to local fluid aggregation. The mantle plume occurs at the interface of another earth sphere, where the uplift force of underplating creates a convex geometry and produces a baking heating effect. As a result, the rheological property of the baked upper materials is enhanced to cause lateral flow, so that the vertical movement of the substance is converted into horizontal motion. The horizontally flowing hot matter accumulates to a certain extent and rises upward to produce vertical motion. Such vertical and horizontal movements are constantly changing, eventually transferring thermal energy from the center of the Earth’s deep core to the shallow crust. This energy transfer can lead to seafloor expansion, plate movement, basin-mountain coupling, etc., and also form different levels of heat-control structure systems. The earth-scale thermostatic tectonic system may be divided into several subsystems: the Earth’s core that is a heat-generating structure; the liquid outer core that is a heat storage structure; mantle plums and high temperature fluids occurring at each sphere constitute the heat-conducting structures; and volcanoes, hot springs and earthquakes on the Earth’s surface form the heat-dissipating structures. The lateral flow of quasi-solid rheological materials in continental crust is the main controlling factor for the formation of dry hot rock, which is of great significance for geothermal exploration of dry hot rock.

Key words: deep geothermal energy, mechanism of heat transmission, deductive reasoning method, first-principles, hot dry rock

中图分类号:

P314.2

罗文行, 孙国强, 周洋, 刘德民, 陈棋. 试论地球深部地热能传输机理[J]. 地学前缘, 2020, 27(1): 10-16.

LUO Wenxing, SUN Guoqiang, ZHOU Yang, LIU Demin, CHEN Qi. Discussion on the mechanism of deep geothermal energy transmission[J]. Earth Science Frontiers, 2020, 27(1): 10-16.

图/表 3

图1 热能从地核向地球浅表传输的构造动力学过程示意图[30]

Fig.1 A schematic diagram showing the tectonic dynamics of geothermal energy transport from the Earth's interior core to the Earth's shallow crust[30]

图2 软流圈层流与大陆下地壳层流及洋陆与盆山形成的深层热机制[30]

Fig.2 A mechanistic model showing the deep heat flow between ocean and continent or basin and mountain driven by laminar flows of asthenosphere and lower continental crust[30]

图3 热能从软流圈向地壳浅表传输的构造运动过程示意图

Fig.3 A schematic plot showing the geothermal energy transport from the asthenosphere to the Earth's crust

参考文献 33

[1]	黄淑芬. 能源发展与环境问题[J]. 资源节约与环保, 2016(9):1.
[2]	王雪松. 我国能源问题与环境发展的战略分析[J]. 环境与发展, 2017, 29(7):18-19.
[3]	徐艺真. 干热岩:高性价比的新兴能源[J]. 中国石化, 2018(10):45-47.
[4]	汪集旸, 胡圣标, 庞忠和, 等. 中国大陆干热岩地热资源潜力评估[J]. 科技导报, 2012, 30(32):25-31.
[5]	廖志杰, 万天丰, 张振国. 增强型地热系统:潜力大、开发难[J]. 地学前缘, 2015, 22(1):335-344.
[6]	李德威. 地球系统动力学与取热减灾减排[J]. 地学前缘, 2014, 21(6):243-253.
[7]	李德威, 郝海健, 刘娇, 等. 华北热灾害链的结构、成因及强震趋势分析[J]. 地学前缘, 2013, 20(6):102-108.
[8]	许天福, 袁益龙, 姜振蛟, 等. 干热岩资源和增强型地热工程:国际经验和我国展望[J]. 吉林大学学报(地球科学版), 2016, 46(4):1139-1152.
[9]	许天福, 张延军, 曾昭发, 等. 增强型地热系统(干热岩)开发技术进展[J]. 科技导报, 2012, 30(32):42-45.
[10]	蔺文静, 刘志明, 马峰, 等. 我国陆区干热岩资源潜力估算[J]. 地球学报, 2012, 33(5):807-811.
[11]	马峰, 蔺文静, 郎旭娟, 等. 我国干热岩资源潜力区深部热结构[J]. 地质科技情报, 2015, 34(6):176-181.
[12]	蔺文静, 甘浩男, 王贵玲, 等. 我国东南沿海干热岩赋存前景及与靶区选址研究[J]. 地质学报, 2016, 90(8):2043-2058.
[13]	郑宇轩, 单文军, 赵长亮, 等. 青海共和干热岩GR1井钻井工艺技术[J]. 地质与勘探, 2018, 54(5):1038-1045.
[14]	阴文行, 冯红喜, 左科峰, 等. 气举反循环钻进技术在干热岩开发中的应用分析[J]. 地质装备, 2017, 18(2):33-37.
[15]	徐立, 王良书, 杨谦. 江苏干热岩地热资源潜力估算[J]. 高校地质学报, 2014, 20(3):464-469.
[16]	石岩, 姜云涛. 我国深层地热资源利用现况分析[J]. 吉林建筑工程学院学报, 2011, 28(2):37-39.
[17]	许天福, 张延军, 于子望, 等. 干热岩水力压裂实验室模拟研究[J]. 科技导报, 2015, 33(19):35-39.
[18]	蔺文静, 王凤元, 甘浩男, 等. 福建漳州干热岩资源选址与开发前景分析[J]. 科技导报, 2015, 33(19):28-34.
[19]	严维德. 共和盆地干热岩特征及利用前景[J]. 科技导报, 2015, 33(19):54-57.
[20]	雷玉德, 童珏, 杨占梅, 等. 青海省干热岩资源类型及典型地热模式[J]. 南水北调与水利科技, 2017, 15(4):117-122.
[21]	张森琦, 文冬光, 许天福, 等. 美国干热岩“地热能前沿瞭望台研究计划”与中美典型EGS场地勘查现状对比[J]. 地学前缘, 2019, 26(2):321-334.
[22]	李德威, 王焰新. 干热岩地热能研究与开发的若干重大问题[J]. 地球科学, 2015, 40(11):1858-1869.
[23]	张旗, 金惟俊, 李承东, 等. 岩浆热场:它的基本特征及其与地热场的区别[J]. 岩石学报, 2014, 30(2):341-349.
[24]	徐传国, 陆士立, 焦仓文, 等. HD-4002B综合测井仪在铀矿科学深钻中的应用[J]. 世界核地质科学, 2015, 32(2):91-95.
[25]	徐珏, 王登红, 陈毓川, 等. 中国大陆科学钻5158 m主孔超高压变质岩中的钛矿化[J]. 矿床地质, 2006, 25(增刊1):55-58.
[26]	骆淼, 潘和平, 赵永刚, 等. 中国大陆科学钻探主孔自然放射性测井及其解释[J]. 地球科学, 2008, 33(5):661-671.
[27]	谭现锋, 王浩, 康凤新. 利津陈庄干热岩GRY₁孔压裂试验研究[J]. 探矿工程(岩土钻掘工程), 2016, 43(10):230-233.
[28]	黄定华, 吴金平, 段怡春, 等. 从内核偏移到板块运动[J]. 科学通报, 2001, 46(8):646-651.
[29]	李德威. 地球三级层流隆陷构造系统的关联机理[J]. 大地构造与成矿学, 2016, 40(4):625-642.
[30]	李德威, 夏义平, 徐礼贵. 大陆板内盆山耦合及盆山成因: 以青藏高原及周边盆地为例[J]. 地学前缘, 2009, 16(3):110-119.
[31]	李德威. 大陆下地壳流动:渠流还是层流?[J]. 地学前缘, 2008, 15(3):130-139.
[32]	李德威. 青藏高原及邻区三阶段构造演化与成矿演化[J]. 地球科学: 中国地质大学学报, 2008(6):723-742.
[33]	李德威. 地震与地热的关联性:从预测减灾到取能减灾[J]. 地球科学与环境学报, 2017, 39(4):563-574.