Present Terrestrial Heat Flow Measurements of the Geothermal Fields in the Chagan Sag of the YingenEjinaqi Basin,Inner Mongolia,China

Owing to the lack o f terrestrial heat flow data, studying lithospheric thermal structure and geodynamics of the Yingen-Ejinaqi Basin in Inner Mongolia is limited. In this paper, the terrestrial heat flow o f the Chagan sag in the YingenEjinaqi Basin were calculated by 193 system steady-state temperature measurements of 4 wells, and newly measuring 62 rock thermal conductivity and 20 heat production rate data on basis o f the original 107 rock thermal conductivity and 70 heat production data. The results show that the average thermal conductivity and heat production rate are 2.11 ±0.28 W/(m.K) and2.42±0.25 nW/m~3 in the Lower Cretaceous o f the Chagan sag. The average geothermal gradient from the Lower Suhongtu 2 Formation to the Suhongtu 1 Fonnation is 37.6 °C/km, and that o f the Bayingebi 2 Formation is 27.4 °C/km. Meanwhile, the average terrestrial heat flow in the Chagan sag is 70.6 mW/m~2. On the above results, it is clear that there is an obvious negative correlation between the thermal conductivity o f the stratum and its geothermal gradient. Moreover, it reveals that there is a geothermal state between tectonically stable and active areas. This work may provide geothermal parameters for further research o f lithospheric thermal structure and geodynamics in the Chagan sag.     

二连盆地白音查干凹陷和乌里雅斯太凹陷岩石热导率测试与分析

岩石热导率是地热理论和应用研究中十分重要的参数,对于地热资源评估、大地热流分析、深部热状态及岩石圈热结构等相关研究提供了基础数据支撑。本文从二连盆地白音查干凹陷和乌利亚斯太凹陷采集了98块基本覆盖白垩系各地层的钻井岩芯样品,在实验室条件下对它们进行了岩石热导率测试,并收集了前人对31个样品的测试结果,进而结合孔隙度、钻孔实测温度和深度数据,对实验室条件下的测试数据进行了饱水校正和温压校正。测试样品包括泥岩、砂岩、砾岩、片岩和玄武岩,孔隙度在2%~20%之间,采样深度在117.8~3159.5m范围内,对应的温度和压力范围分别为13.5~118.6℃、2.89~77.41MPa。实测结果表明5种不同岩性岩石样品的热导率变化范围为0.89~4.91W/(m·K)。经过饱水和温压校正后,泥岩、砂岩、砾岩、页岩和玄武岩的平均热导率分别为2.08±0.36W/(m·K)、2.28±0.50W/(m·K)、2.53±0.44W/(m·K)、4.16±0.76W/(m·K)、1.33±0.09W/(m·K)。5种岩性中片岩平均热导率值最大,玄武岩平均热导率值最小,沉积岩介于两者之间,总体上具有随深度增大而增加的趋势。饱水、温度和压力校正后的热导率比干样热导率高。结合研究区内各个地层砂岩和泥岩所占比计算得到白音查干凹陷和乌里雅斯太凹陷白垩系地层热导率分别为2.00W/(m·K)和2.17W/(m·K)。结合钻孔测温数据,计算得到二连盆地大地热流值介于74~85mW/m^2,明显高于中国大陆地区平均热流值61.5mW/m^2。本文的研究成果对二连盆地以及华北北缘的地热资源,深部热状态和岩石圈结构都有意义。     

淮北煤田现今地温场特征及大地热流分布

淮北煤田的高温热害问题愈发突出,但目前对该区系统的地温场特征及大地热流分布研究非常稀少.在系统分析淮北煤田大量地面钻孔井温测井数据和井下巷道围岩温度测试数据的基础上,结合72块岩石样品的热导率测试结果,全面阐述了该区现今地温梯度和大地热流的分布特征.研究表明:淮北煤田现今地温梯度众值介于1.80~2.80 ℃/100 m之间,平均地温梯度为2.42 ℃/100 m;大地热流值变化范围为39.52~74.12 mW/m2,平均热流值为55.72 mW/m2,地温梯度和热流值均低于同处华北板块的其他盆地以及南部的淮南煤田;大地热流受地温梯度控制明显,两者分布较为相似,整体表现为南高北低、西高东低的特点.结果表明,区内现今地温场和热流分布主要受区域地质背景和区内构造格局的控制.      

Present Geothermal Fields of the Dongpu Sag in the Bohai Bay Basin

The Dongpu sag is located in the south of the Bohai Bay basin, China, and has abundant oil and gas reserves. To date, there has been no systematic documentation of its geothermal fields. This study measured the rock thermal conductivity of 324 cores from 47 wells, and calculated rock thermal conductivity for different formations. The geothermal gradient and terrestrial heat flow were calculated for 192 wells on basis of 892 formation-testing data from 523 wells. The results show that the Dongpu sag is characterized by a medium-temperature geothermal field between stable and active tectonic areas, with an average geothermal gradient of 32.0°C/km and terrestrial heat flow of 65.6 mW/m2. The geothermal fields in the Dongpu sag is significantly controlled by the Changyuan, Yellow River, and Lanliao basement faults. They developed in the Paleogene and the Dongying movement occurred at the Dongying Formation depositional period. The geothermal fields distribution has a similar characteristic to the tectonic framework of the Dongpu sag, namely two subsags, one uplift, one steep slope and one gentle slope. The oil and gas distribution is closely associated with the present geothermal fields. The work may provide constraints for reconstructing the thermal history and modeling source rock maturation evolution in the Dongpu sag.     

Characteristics and Formation Mechanism of the Geothermal Field in the North China Downfaulted Basin

The geothermal field is mainly controlled by the regional tectonic framework characterized by alternationsof uplifted and depressed basement. and exhibits a similar zoned distribution of temperatures. In the upliftedarea the geothermal gradient (G) and terrestrial heat flow value(q) of the Cenozoic sedimentary cover are rela-tively high, with G=3.5-5.0℃/100m and q=63-84mW/m~2; whereas in the depressions they are rela-tively low, with G=2.7-3.5℃/100m and q=46-59mW/m~2. In the whole region, G=3.58℃/100m and q=61.5±13.4nW/m~2, indicating a comparatively high geothermal background and the presence of localgeothermal anomalies. A comparison of the results of mathematical simulation of the geothermal field with themeasured values shows a good agrecment between them. The geothermal difference between various tectonicunits is caused chiefly by the lateral and vertical variation of thermal properties of shallow crustal rocks. Thisphenomenon can be regarded as the result of redistribution of relatively uniform heat flows from the deep crustin the surficial part of the crust in the process of their upward conduction.     

Estimating heat flow from an unsteady temperature log of submarine borehole BDP-98 (Lake Baikal)

We have applied the method of one temperature log suggested by Kutasov in 1987 to process an unsteady temperature log of the 674 m deep submarine borehole BDP-98-2 (Akademichesky Ridge, Lake Baikal) and found it suitable to reconstruct the primary steady thermal gradient not disturbed by drilling. The steady gradient we derived using a special formalism, with reference to drilling conditions and measured thermal properties of sediments, was 63 mK/m, more than two times the unsteady gradient at different depths. Heat flow calculated with this gradient and a mean thermal conductivity of 1.1 W/(m·K) was 70 mW/m², which is consistent with earlier geothermal data from the same area. Thus, the one-log procedure is a useful tool to predict the original undisturbed thermal gradients and estimate approximate heat flows if a single unsteady temperature log is available.     

Heat flow and thermal modeling of the Yinggehai Basin, South China Sea

Geothermal gradients are estimated to vary from 31 to 43 °C/km in the Yinggehai Basin based on 99 temperature data sets compiled from oil well data. Thirty-seven thermal conductivity measurements on core samples were made and the effects of porosity and water saturation were corrected. Thermal conductivities of mudstone and sandstone range from 1.2 to 2.7 W/m K, with a mean of 2.0±0.5 W/m K after approximate correction. Heat flow at six sites in the Yinggehai Basin range from 69 to 86 mW/m², with a mean value of 79±7 mW/m². Thick sediments and high sedimentation rates resulted in a considerable radiogenic contribution, but also depressed the heat flow. Measurements indicate the radiogenic heat production in the sediment is 1.28 μW/m³, which contributes 20% to the surface heat flow. After subtracting radiogenic heat contribution of the sediment, and sedimentation correction, the average basal heat flow from basement is about 86 mW/m².Three stages of extension are recognized in the subsidence history, and a kinematic model is used to study the thermal evolution of the basin since the Cenozoic era. Model results show that the peak value of basal heat flow was getting higher and higher through the Cenozoic. The maximum basal heat flow increased from 65 mW/m² in the first stage to 75 mW/m² in the second stage, and then 90 mW/m² in the third stage. The present temperature field of the lithosphere of the Yinggehai Basin, which is still transient, is the result of the multistage extension, but was primarily associated with the Pliocene extension.     

贵州主要城市浅层地热能利用潜力评价

作为清洁、新型、可再生的绿色能源,浅层地热能对缓解城市节能、减排等问题有很大的帮助。为评价贵州省贵阳市、遵义市、兴义市、铜仁市、六盘水市、凯里市、都匀市、毕节市、安顺市及贵安新区10个地级市和国家级经济开发区的浅层地热能利用潜力,文章根据浅层地热能赋存环境调查、现场热响应试验及岩土体热物性测试结果等综合分析,计算出贵州主要城市地表以下100 m深度内的浅层地热能总热容量为35.20×1013kJ·℃-1,夏季换热功率为520.2×104kW,冬季换热功率为342.3×104kW;并在此基础上,评价了贵州主要城市浅层地热能的资源潜力,夏季可制冷面积为7.43×108 m2,冬季可供暖面积为6.51×108m2。      

孤岛油田馆陶组热储地热资源开发利用分析

孤岛油田蕴藏丰富的中、低温地热资源,对其进行合理的开发利用,对推进该区新、旧热能转换,促进地方经济发展具有重要意义。在总结以往勘探成果的基础上,查明了孤岛油田为大地热流高值异常区,平均值为72.62 mW/m²。重点研究馆陶组热储地热地质条件,查明了馆陶组下段热储厚度为106~145 m,平均孔隙度约为30%,热储温度为75.5~82 ℃,单位降深涌水量为3.71~10.55 m³/(h·m),是地热资源开发的有利目标热储。采用热储法估算区内馆陶组下段热储中蕴藏的地热资源量为3.745×10¹⁸ J,折合标准煤量1.28亿t,地热水储存量约为60.87×10⁸ m³; 采用开采强度法估算的该区地热水允许开采量约为253万m³/a,可支持供暖面积约100万m²。     

确定中、新生代沉积盆地大地热流的方法

用传统的方法于年青的沉积盆地测试大地热流,存在的问题多且难度大,因而这些盆地一直是世界热流测试研究最薄弱的地区之一。本文在符合热流测试原理的前提下,尝试用一种较容易确定热流值的方法,虽然这种方法获得的数据是近似值,但是可以接受的,并有地质、地球物理意义。也简要论述在新生界盖层地温梯度图的基础上,确定一个合理的系数,即盖层的平均热导率值,将地温梯度图转换为热流图,用以反映盆地地热的基本面貌。     

Geothermal gradients and heat flow variations in parts of the eastern Niger delta,Nigeria

Geothermal gradients and present day heat flow values were evaluated for about seventy one wells in parts of the eastern Niger delta, using reservoir and corrected bottom–hole temperatures data and other data collected from the wells. The results showed that the geothermal gradients in the shallow/continental sections in the Niger delta vary between 10 - 18° C/km onshore, increasing to about 24° C/km seawards, southwards and eastwards. In the deeper (marine/paralic) section, geothermal gradients vary between 18 - 45° C/km. Heat flow values computed using Petromod 1–D modeling software and calibrated against corrected BHT and reservoir temperatures suggests that heat flow variations in this part of the Niger delta range from 29–55 mW/m² (0.69–1.31 HFU) with an average value of 42.5 mW/m² (1.00 HFU). Heat flow variations in the eastern Niger delta correspond closely to variations in geothermal gradients. Geothermal gradients increase eastwards, northwards and seawards from the coastal swamp. Vertically, thermal gradients in the Niger delta show a continuous and non-linear relationship with depth, increasing with diminishing sand percentages. As sand percentages decrease eastwards and seawards, thermal gradient increases. Lower heat flow values (< 40 mW/m²) occur in the western and north central parts of the study area. Higher heat flow values (40 - 55 mW/m²) occur in the eastern and northwestern parts of the study area. A significant regional trend of eastward increase in heat flow is observed in the area. Other regional heat flow trends includes; an eastwards and westwards increase in heat flow from the central parts of the central swamp and an increase in heat flow from the western parts of the coastal swamp to the shallow offshore. Vertical and lateral variations in thermal gradients and heat flow values in parts of the eastern Niger delta are influenced by certain mechanisms and geological factors which include lithological variations, variations in basement heat flow, temporal changes in thermal gradients and heat flow, related to thicker sedmentary sequence, prior to erosion and evidenced by unconformities, fluid redistribution by migration of fluids and different scales of fluid migration in the sub-surface and overpressures.     

冀中坳陷束鹿凹陷地热系统成因模式

地热系统内部地质要素特征分析是建立其成因模式的基础,也是后期研究地热资源赋存特征和资源量评价的依据。结合前人研究成果和区内地热钻井资料,通过对冀中坳陷束鹿凹陷地热系统“源、储、通、盖”主要地质要素分析,建立了其概念模型,并开展了地热资源量评价。束鹿凹陷为一新生代发育在渤海湾盆地冀中坳陷内的典型的箕状凹陷,接受可能来自于其下深部地壳结构约20 km处低阻体的热源供给。新近系馆陶组砂岩热储和奥陶系碳酸盐岩热储分别构成了两套独立的地热系统。其中,馆陶组砂岩热储全区稳定分布,底板埋深介于1100~2000 m,储层厚度约为200~320 m,孔隙度约在15%~35%之间,渗透率最高可达1200 mD,热储底板温度在57~78℃;奥陶系碳酸盐岩热储受箕状凹陷边界断裂的控制呈单斜状倾伏,埋深1800~6000 m,储层厚度100~550 m,孔隙度2%~18%,渗透率0.5~50 mD,地热水井口温度在75~92℃。两套地热系统由西边太行山的大气降水沿着地层不整合面和断裂运移通道进行补给,通过深部热传导和局部热对流增温后,在储层中富集形成地热水。上覆松散的第四系沉积和明化镇组河流相碎屑岩沉积厚300~1400 m,热导率0.9~1.8 W/(m·K),构成了良好的区域盖层。束鹿凹陷地热资源量评价结果表明,馆陶组砂岩地热系统含244.430×10⁸ GJ,奥陶系岩溶地热系统 含203.752×10⁸ GJ,总量合计448.182×10⁸ GJ,折合标煤15.296×10⁸ t。年开采地热资源量满足的供暖面积可达1.106×10⁸ m2,开发潜力巨大。     

A preliminary study on the potential of the geothermal resources around the Gulf of Suez, Egypt

The Gulf of Suez is characterized by the presence of many hot springs and deep thermal wells scattered around its coastal areas. So it is considered one of the promised geothermal areas in Egypt. In this study, the main emphasis is to investigate the geothermal potential around the Gulf of Suez using the available logging and geothermometer datasets. The temperature profiles and well logging data of some hot springs and deep wells around or within the coastal area of the Gulf of Suez are used in this study. The temperature profiles are analyzed and some important thermophysical properties are estimated (geothermal gradient, thermal conductivity, heat flow, and specific heat capacity). Such analysis revealed that a medium to high geothermal gradient (22.0–30°C/Km) is given for the Gulf of Suez as a whole, with some spots of much higher gradient in the order of 35.0–44°C/Km (Ras Fanar and Hammam Faraun areas). The compiled thermal plots show that the thick evaporites and rock salt lithology, which is a major constituent in this area, attain the highest thermal conductivity (>3.10 W/m/K) and heat flow (>90 mW/m²) and the lowest specific heat capacity (<0.30 J/kg/K). The available gamma ray and the natural gamma ray spectroscopy logs are used to conduct a radioactive-based heat generation study using the characteristic radioactive nature of some elements like; ²³⁸U, ²³⁵U, ²³²Th, and of the isotope of ⁴⁰K. A good linearity is observed between the heat production (A in microwatt per cubic meter) and the gamma ray (API) along a wide range of datasets (0–150 API) in all wells. The heat production factor increases in the carbonate lithology (up to 3.20?μW/m³) and is proportional to the shale volume. A geothermometer-based study is used to estimate the subsurface formation temperature and heat flow from the geochemical analysis of some water samples collected from the studied hot springs. The estimated thermal parameters are in harmony with the regional thermal regime concluded form logging data. A thermal basin growth study, in relation to the clay diagenesis is conducted concerning the thermal effects that take place with depth giving rise to another clay mineral (illite). Furthermore, a number of 2D thermal–burial history diagrams are constructed for the complied sections of some of the studied areas to show the vertical distribution of the estimated petrothermal properties. A reserve evaluation study is carried out to estimate the economic geothermal capacity of these hot springs to be used as alternative clean source for possible energy production (electricity) and other low-temperature purposes.     

淮南煤田现今地温场特征

在系统分析淮南煤田大量地面钻孔井温测井数据和井下巷道围岩温度测试数据的基础上,结合58块岩石样品的热导率测试结果,全面阐述了该区现今地温梯度和大地热流的分布特征。研究表明,淮南煤田现今地温梯度的众值介于2.50~3.50℃/hm之间,平均地温梯度为2.9℃/hm;大地热流值变化范围为31.87~83.9 m W/m2,平均热流值为63.69 m W/m2,地温梯度和热流值区均高于淮北煤田;大地热流受地温梯度控制明显,其变化特征和地温梯度分布较为相似,整体表现为中东部高,西部其次,东南部最小的特征。分析揭示,区内现今地温场和热流分布主要受区域地质背景和区内构造格局的控制。     

河间潜山地热资源开发方案数值模拟

古潜山地热资源具备岩溶孔隙发育程度高、热储面积厚度大、地热水储量大的优点。冀中坳陷内古潜山分布密集且地热资源丰富, 河间潜山位于冀中坳陷饶阳凹陷中东部, 具有良好的地热地质条件, 开发潜力巨大。本文基于河间潜山及其周缘地区测井资料、岩石热物性并进行了计算, 发现其地温梯度为29.8 ℃/km到44.5 ℃/km之间, 平均值为40.7 ℃/km。大地热流值介于64.8~80.6 mW/m2之间, 平均值为 73.4 mW/m2。通过水热耦合模拟方法模拟选定的地热资源有利区的温度变化, 结果发现河间潜山合理的开采井距为800 m, 合理开采量为60 L/s, 回灌温度为35 ℃, 总可开采量为6.32×1016 J, 单年可开采量为 6.32×1014 J, 可供暖面积为1.22×106 m2, 对于冀中坳陷潜山地热资源的开发利用具有一定的指导意义。     

柴达木盆地地温场分布特征及控制因素

含油气盆地的地温场在油气的生成、运聚及盆地演化过程中起着十分重要的作用。柴达木盆地是中国西部重要的含油气盆地,位于喜马拉雅构造域的东北部,盆地现今地温场特征研究不仅为柴达木盆地及周缘陆内或板内大陆动力学及盆地动力学研究提供了科学依据,同时也是油气成烃、成藏及资源评价等工作的研究基础。柴达木盆地现今地温场研究的前期工作主要集中在盆地西部,盆地的北缘、东部开展的工作很少,所用研究数据多取自20世纪之前,盆地现今地温场特征的系统研究尚比较缺乏,亟须开展相关研究工作。文中采用先进的钻孔温度连续采集系统,实现了深井稳态测温工作的大规模化、高精度化,使用光学扫描法测试岩石热导率,获得了批量的、高精度的岩石热导率数据,新增了17口钻井的测温剖面。研究表明：柴达木盆地现今地温梯度平均为(28.6±4.6) ℃/km,地温梯度分布具有西部高,中、东部低的特点。柴达木盆地现今大地热流值平均(55.1±7.9) mW/m2,盆地不同构造单元大地热流分布存在差异。大地热流分布特征表明：柴达木盆地总体属于温盆,热流值低于我国大陆地区大地热流平均值,但高于西部的塔里木、准噶尔盆地。柴达木盆地现今地温场分布特征受地壳深部结构、岩石热导率性质及盆地构造等因素的控制。     

红河流域元古界大红山群变质岩系的热储结构及热流特征

经过地热地质调查、物探验证和分析论证,在红河流域中段的戛洒盆地古元古界大红山群变质岩系中钻探获得了可供开发利用的热矿水。勘探孔深2 200.71 m,大红山群第4至第5段（Pt₁dhs4-5）热储层富水性强,钻孔涌水量1 089 m3·d?1,孔底测温84.3 ℃,地热水矿化度9 777 mg·L?1,水化学类型为Cl-Na型,水化学成分复杂。此次成功的勘探研究,揭示了大红山变质岩系的热储特征及地热资源潜力,拓展了地热水勘探开发的新领域。综合研究认为,大红山群变质岩系中的硬脆性大理岩、石英片岩、火成岩等热储层（带）、导热导水的深大断裂及上覆隔水隔热的三叠系红层等盖层,构成了较为典型的带状热储。热储层赋存承压地热水,主要由地下水在重力和热力作用下,沿区域深大断裂带的主干和次级导热导水断裂作深循环逐渐增温和对流运动所形成,实测地热增温率为3.0 ℃·(100 m)?1。      

Absence of a regional surface thermal high in the Baikal rift; new insights from detailed contouring of heat flow anomalies

Heat flow in active tectonic zones as the Baikal rift is a crucial parameter for evaluating deep anomalous structures and lithosphere evolution. Based on the interpretation of the existing datasets, the Baikal rift has been characterized in the past by either high heat flow, or moderately elevated heat flow, or even lacking a surface heat flow anomaly. We made an attempt to better constrain the geothermal picture by a detailed offshore contouring survey of known anomalies, and to estimate the importance of observed heat flow anomalies within the regional surface heat output. A total of about 200 new and close-spaced heat flow measurements were obtained in several selected study areas in the North Baikal Basin. With an outrigged and a violin-bow designed thermoprobe of 2–3-m length, both the sediment temperature and thermal conductivity were measured. The new data show at all investigated sites that the large heat flow highs are limited to local heat flow anomalies. The maximum measured heat flow reaches values of 300–35000 mW/m², but the extent of the anomalies is not larger than 2 to 4 km in diameter. Aside of these local anomalies, heat flow variations are restricted to near background values of 50–70 mW/m², except in the uplifted Academician zone. The extent of the local anomalies excludes a conductive source, and therefore heat transport by fluids must be considered. In a conceptual model where all bottom floor heat flow anomalies are the result of upflowing fluids along a conduit, an extra heat output of 20 MW (including advection) is estimated for all known anomalies in the North Baikal Basin. Relative to a basal heat flow of 55–65 mW/m², these estimations suggest an extra heat output in the northern Lake Baikal of only 5%, corresponding to a regional heat flow increase of 3 mW/m². The source of this heat can be fully attributed to a regional heat redistribution by topographically driven ground water flow. Thus, the surface heat flow is not expected to bear a signal of deeper lithospheric thermal anomalies that can be separated from heat flow typical for orogenically altered crust (40–70 mW/m²). The new insights on the geothermal signature in the Baikal rift once more show that continental rifting is not by default characterized by high heat flow.     

双U型地埋管换热器换热性能试验研究

双U型地埋管换热器(DUBTHE)在实际应用中易出现管路交叉,引起热短路,造成换热性能降低,直接影响浅层地源热泵系统的运行效率。以西安某浅层地源热泵项目为工程背景,基于无限长线热源理论和斜率法,通过现场岩土热响应试验、不同测温法测温试验,研究了岩土初始平均温度、导热系数和体积热容,及管卡间距对DUBTHE换热性能的影响。结果表明：多点式测温线缆测得的岩土初始平均温度为17.08℃,更接近实际地层温度。该地层的岩土综合导热系数和综合体积热容分别为1.65 W/(m·K)、2.81×10⁶ J/(m³·K)。DN25 DUBTHE的夏、冬季单位延米换热量随着管卡间距减小而增加,且增速随管卡间距的减小先增大后减小。当管卡间距分别为1、2、3、4 m时,DN25 DUBTHE的夏季单位延米换热量较无管卡分别提高了21.03%、19.48%、15.16%、3.92%;DN25 DUBTHE的冬季单位延米换热量较无管卡分别提高了20.83%、19.48%、14.94%、3.79%。工程中最优的管卡布置方式为2 m或3 m管卡间距的DN25 DUBTHE。...     

江汉盆地当阳复向斜当深3井热史恢复及其油气勘探意义

江汉盆地当阳复向斜当深3井实测地温剖面和样品热导率测试结果表明:其现今地温梯度为20～24℃/km,热流值为56mW/m²,体现了盆地发育于扬子稳定陆块的大地构造属性。基于7个磷灰石裂变径迹样品和大量镜质体反射率古温标数据进行的热史恢复表明,盆地构造—热演化经历了前印支期的低热流(50～60mW/m²)和小剥蚀量(50～200m),印支期的高热流(约80mW/m²)及燕山期与喜马拉雅期的低热流(50～60mW/m²)与大剥蚀量(1100～2400m)的不同演化阶段,反映了盆地和区域构造演化过程的阶段性。受沉积剥蚀及盆地构造—热演化的控制,生油岩系的生烃阶段与过程具有多期次的特征。