CN106153666A - The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history - Google Patents
The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history Download PDFInfo
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Abstract
The present invention provides the analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of a kind of different buried history, under the conditions of this difference buried history, the analogy method of hydrocarbon source rock repeatedly hydrocarbon feature includes: step 1, selection core sample: step 2, carry out the mensuration of sample maturity degree: step 3, carry out the recovery of basin fill buried history;Step 4, is simulated hydrocarbon experiment;And step 5, analyze in the kind sum statistics of variables that each dummy run phase generates goods and materials according to sample, sum up its different hydrocarbon feature.During under the conditions of this difference buried history, the analogy method of hydrocarbon source rock repeatedly hydrocarbon feature solves differing maturity hydrocarbon source rock hydrocarbon, different phase generates diversity and the feature of goods and materials, the hydrocarbon process of the hydrocarbon source rock under the conditions of different buried history and feature can be recovered, accurately calculate resource potential.
Description
Technical field
The present invention relates to oil field development technical field, especially relate to the analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of a kind of different buried history.
Background technology
Hydrocarbon thermal simulation experiment is the important means of Hydrocarbon Generation potentiality and resource assessment, reproducibly organic pyrolysis evolutionary process in plastid, experimental simulation device system mainly has open system and closed system two kinds, open system simulation organic initial cracking reaction, the second pyrolysis reaction of closed system Simulation of Crude Oil and natural gas.By the simulation experiment study of Organic Matter Hydrocarbon Generation under the different experimental conditions such as temperature, pressure, aqueous medium and mineral, experiment condition is made to try one's best close to geology physical condition, result can disclose the Evolvement of hydrocarbon history and sedimentary basin, provides important parameter for basin modelling.
Conventional hydrocarbon thermal simulation experiment compares the hydrocarbon feature during the thermal evolution that emphasis hydrocarbon source rock is single, and pay close attention to less for experiencing the feature of the hydrocarbon of many phases of the more complicated hydrocarbon source rock of a lot of tectonic movements, buried history and thermal evolution history, we have invented the analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of a kind of new different buried history for this, solve above technical problem.
Summary of the invention
The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of the different buried history of the hydrocarbon feature simulation that it is an object of the invention to provide a kind of many phases time for the hydrocarbon source rock reaching different evolution level under the conditions of different buried history.
The purpose of the present invention can be achieved by the following technical measures: the analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history, under the conditions of this difference buried history, the analogy method of hydrocarbon source rock repeatedly hydrocarbon feature includes: step 1, selection core sample: step 2, carry out the mensuration of sample maturity degree: step 3, carry out the recovery of basin fill buried history;Step 4, is simulated hydrocarbon experiment;And step 5, analyze in the kind sum statistics of variables that each dummy run phase generates goods and materials according to sample, sum up its different hydrocarbon feature.
The purpose of the present invention realizes also by following technical measures:
In step 1, when choosing core sample, choose and be in different configuration band, different buried depth, there is the sample of different burial history, different lithology, carry out next step analytical test.
In step 2, the sample being in different configuration band, different buried depth and different burial history is carried out the mensuration of thermal evolutionary maturity, according to measurement result, the sample of the different lithology choosing different configuration band, different burial history, different evolution grade is simulated hydrocarbon experiment.
In step 3, sample to the different evolution grade being in different configuration band, recovers the depositional and burial history on residing structural belt stratum, the erosion sediment thickness of renwing stratum and the primary deposit thickness on stratum, in conjunction with the research of geothermal history, recover the thermal evolution history of sample.
In step 3, use structural feature to analyze basin-mountain frame work history, by the erosion sediment thickness in balanced cross section method renwing stratum each period, in conjunction with the thermal evolution history in area, recover its burial evolution history.
In step 4, choosing differing maturity, the hydrocarbon source rock of different lithology carries out the hydrocarbon simulation experiment of one-time continuous hydrocarbon simulation experiment and discontinuous respectively, kind and quantity to the thermal simulation product under the conditions of various are added up.
In step 4, hydrocarbon simulation experiment uses closed system, reacts and carries out in the rustless steel container closed, and this hydrocarbon device has 7 heating chambers, and each heating chamber can individually temperature control, pressure control.
In steps of 5, differing maturity the hydrocarbon source rock kind of product, quantity, total amount under the conditions of different simulation experiments are analyzed, the simulation hydrocarbon feature of hydrocarbon source rock under the conditions of the different buried history of summary, the structural evolution in binding district and thermal evolution history, the hydrocarbon history of evaluation hydrocarbon source rock and the hydrocarbon type in each stage and total amount.
The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history in the present invention, hydrocarbon source rock diversity of hydrocarbon feature in the earth history evolutionary process in later stage that the evolution level that causes under the conditions of relating to different burial history is different, in the case of a lot of hydrocarbon especially for the hydrocarbon source rock on the old stratum such as Paleozoic group, buried history and Thermal History in conjunction with stratum, the hydrocarbon process of the hydrocarbon source rock under the conditions of different buried history and feature can be recovered, accurately calculate resource potential.This method is simulated for the hydrocarbon feature of many phases time of the hydrocarbon source rock reaching different evolution level under the conditions of different buried history, sums up the hydrocarbon feature under its different evolutionary process and different evolution grade, provides parameter accurately for resource potential evaluation.
Accompanying drawing explanation
Fig. 1 be the present invention different buried history under the conditions of the flow chart of a specific embodiment of analogy method of hydrocarbon source rock repeatedly hydrocarbon feature;
Fig. 2 be the present invention a specific embodiment in Linqing Depression upper palaeozoic buried history type map;
Fig. 3 be the present invention a specific embodiment in continuously with secondary simulation water vapour transfer and the schematic diagram of the relation of temperature;
Fig. 4 be the present invention a specific embodiment in relatively low initial Maturity secondary gas generation amount account for the schematic diagram of continuous amount of coalbed methane generated ratio;
Fig. 5 be the present invention a specific embodiment in medium initial Maturity secondary gas generation amount account for the schematic diagram of continuous amount of coalbed methane generated ratio;
Fig. 6 be the present invention a specific embodiment in higher initial Maturity secondary gas generation amount account for the schematic diagram of continuous amount of coalbed methane generated ratio;
Fig. 7 be the present invention a specific embodiment in Eastern Linqing Depres Sion source rocks in coal measures secondary gas generation plate;
Fig. 8 be the present invention a specific embodiment in Eastern Linqing Depres Sion source rocks in coal measures once with secondary aerogenesis total amount hydrocarbon figure.
Detailed description of the invention
For making the above and other objects, features and advantages of the present invention to become apparent, cited below particularly go out preferred embodiment, and coordinate shown in accompanying drawing, be described in detail below.
As it is shown in figure 1, the flow chart of the hydrocarbon source rock repeatedly analogy method of hydrocarbon feature under the conditions of the different buried history that Fig. 1 is the present invention.
In step 101, core sample selects.When choosing the samples such as core, choose and be in different configuration band, different buried depth, there is the sample of different burial history, different lithology, carry out next step analytical test.
In step 102, sample maturity degree measures.The sample being in different configuration band, different buried depth and different burial history is carried out the mensuration of thermal evolutionary maturity, according to measurement result, the sample of the different lithology choosing different configuration band, different burial history, different evolution grade is simulated hydrocarbon experiment.
In step 103, basin fill burial history reconstruction.Sample to the different evolution grade being in different configuration band, recovers the depositional and burial history on residing structural belt stratum, the erosion sediment thickness of renwing stratum and the primary deposit thickness on stratum, in conjunction with the research of geothermal history, recovers the thermal evolution history of sample.In one embodiment, carry out recovering research to different evolution grade, the burial evolution history of different configuration carry sample.Use structural feature to analyze basin-mountain frame work history, by the erosion sediment thickness in the method renwing stratum such as balanced cross section each period, combine regional thermal evolution history, recover its burial evolution history.As shown in Figure 2, Linqing Depression upper palaeozoic buried history type can be divided into three kinds of big types, it is Continuous Settlement type, complicated heavy stripping type respectively and continues grand stripping type, according to the relation between denuded strata thickness and later deposition formation thickness complexity sunk stripping type and be further subdivided into 4 kinds of buried history types.The sample choosing different buried history type and evolution grade enters into step 104.
In step 104, simulation hydrocarbon experiment.Choose differing maturity, the hydrocarbon source rock of different lithology carries out the hydrocarbon simulation experiment of one-time continuous hydrocarbon simulation experiment and discontinuous respectively, adds up the kind of the thermal simulation product under the conditions of various and quantity etc..In one embodiment, experiment uses closed system, reacts and carries out in the rustless steel container closed, and this hydrocarbon device has 7 heating chambers, and each heating chamber can individually temperature control, pressure control.
In step 105, analyze in the kind sum statistics of variables that each dummy run phase generates goods and materials according to sample, sum up its different hydrocarbon feature.Differing maturity the hydrocarbon source rock kind of product, quantity, total amount etc. under the conditions of different simulation experiments are analyzed, the simulation hydrocarbon feature of hydrocarbon source rock under the conditions of the different buried history of summary, the structural evolution in binding district and thermal evolution history, the hydrocarbon history of accurate evaluation hydrocarbon source rock and the hydrocarbon type in each stage and total amount.Fig. 3 is continuously and secondary simulates the relation of water vapour transfer and temperature, and essential difference is between 300 DEG C-350 DEG C and 400 DEG C-500 DEG C in temperature;Fig. 4 to Fig. 6 is secondary gas generation amount and once add secondary gas generation amount and account for the graph of a relation of continuous amount of coalbed methane generated ratio, display differing maturity sample enters secondary gas generation process, although the total amount once generated with secondary is less than the most angry total amount, but there is certain difference, sample maturity degree can be divided into three intervals, is 0.7~0.9,0.9~1.6 respectively, more than 1.6.Can set up Linqing Depression Upper Paleozoic source rocks gas generating yield plate accordingly, Fig. 7 is Eastern Linqing Depres Sion source rocks in coal measures secondary gas generation plate, Fig. 8 be Eastern Linqing Depres Sion source rocks in coal measures once with secondary aerogenesis total amount hydrocarbon plate.
The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history in the present invention, there is on different configuration band the sample of different evolution level and buried history carry out the simulation of hydrocarbon by choosing to be in, determine diversity and the feature of different sample simulation product, set up angry plate, provide parameter accurately for Resource predication evaluation.For the analogy method of hydrocarbon source rock hydrocarbon again of the burial history and Thermal History that experienced by complexity, solve different phase during differing maturity hydrocarbon source rock hydrocarbon and generate diversity and the feature of goods and materials.Apply this technology that the hydrocarbon process of Linqing Depression Upper Part of Palaeozoic Coal System hydrocarbon source rock is simulated, provide parameter accurately for correct resource potential of evaluating.Apply this technology to make a breakthrough in the exploration of Linqing Depression coal-formed gas, and predict Linqing Depression coal-formed gas oil in place about 242,600,000,000 side.
Being embodied as the present invention above being described and illustrating, these embodiments should be considered to be only exemplary, is not used to limit the invention, and the present invention should explain according to feature described in appended claims.
Claims (8)
1. the analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history, it is characterised in that under the conditions of this difference buried history, the analogy method of hydrocarbon source rock repeatedly hydrocarbon feature includes:
Step 1, selection core sample:
Step 2, carries out the mensuration of sample maturity degree:
Step 3, carries out the recovery of basin fill buried history;
Step 4, is simulated hydrocarbon experiment;And
Step 5, analyzes in the kind sum statistics of variables that each dummy run phase generates goods and materials according to sample, sums up its different hydrocarbon feature.
The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history the most according to claim 1, it is characterized in that, in step 1, when choosing core sample, choose and be in different configuration band, different buried depth, there is the sample of different burial history, different lithology, carry out next step analytical test.
The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history the most according to claim 1, it is characterized in that, in step 2, the sample being in different configuration band, different buried depth and different burial history is carried out the mensuration of thermal evolutionary maturity, according to measurement result, the sample of the different lithology choosing different configuration band, different burial history, different evolution grade is simulated hydrocarbon experiment.
The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history the most according to claim 1, it is characterized in that, in step 3, sample to the different evolution grade being in different configuration band, the depositional and burial history on residing structural belt stratum is recovered, the erosion sediment thickness of renwing stratum and the primary deposit thickness on stratum, in conjunction with the research of geothermal history, recover the thermal evolution history of sample.
The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history the most according to claim 4, it is characterized in that, in step 3, structural feature is used to analyze basin-mountain frame work history, erosion sediment thickness by balanced cross section method renwing stratum each period, in conjunction with the thermal evolution history in area, recover its burial evolution history.
The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history the most according to claim 1, it is characterized in that, in step 4, choose differing maturity, the hydrocarbon source rock of different lithology carries out the hydrocarbon simulation experiment of one-time continuous hydrocarbon simulation experiment and discontinuous respectively, and kind and quantity to the thermal simulation product under the conditions of various are added up.
The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history the most according to claim 6, it is characterized in that, in step 4, hydrocarbon simulation experiment uses closed system, react and carry out in the rustless steel container closed, this hydrocarbon device has 7 heating chambers, and each heating chamber can individually temperature control, pressure control.
The analogy method of hydrocarbon source rock repeatedly hydrocarbon feature under the conditions of different buried history the most according to claim 1, it is characterized in that, in steps of 5, differing maturity the hydrocarbon source rock kind of product, quantity, total amount under the conditions of different simulation experiments are analyzed, the simulation hydrocarbon feature of hydrocarbon source rock under the conditions of the different buried history of summary, the structural evolution in binding district and thermal evolution history, the hydrocarbon history of evaluation hydrocarbon source rock and the hydrocarbon type in each stage and total amount.
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CN108267434A (en) * | 2018-02-06 | 2018-07-10 | 中国地质大学(武汉) | Indicate the hydrocarbon primary rock producing hydrocarbon process fluorescence in situ observation device of oil inclusions maturity |
CN108344721A (en) * | 2018-02-06 | 2018-07-31 | 中国地质大学(武汉) | Study the generation and expulsion modeling device of oil inclusions fluorescence color and its maturity relationship |
CN109100484A (en) * | 2018-07-31 | 2018-12-28 | 成都理工大学 | A kind of hydrocarbon history research method under thermal history and hydrocarbon thermal simulation constraint |
CN110568149A (en) * | 2018-06-05 | 2019-12-13 | 中国石油化工股份有限公司 | Fine and rapid quantitative simulation method for hydrocarbon generation and discharge history of sedimentary basin hydrocarbon source rock |
CN110726655A (en) * | 2018-07-16 | 2020-01-24 | 中国石油化工股份有限公司 | Experimental method for simulating shale organic pore evolution process |
CN110954969A (en) * | 2019-10-28 | 2020-04-03 | 中国石油大港油田勘探开发研究院 | Method for judging and identifying hydrocarbon generation period of ancient hydrocarbon source rock |
CN117786978A (en) * | 2023-12-27 | 2024-03-29 | 成都理工大学 | Method and system for evaluating influence effect of salt rock deposition on thermal evolution of hydrocarbon source rock under salt |
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CN108267434A (en) * | 2018-02-06 | 2018-07-10 | 中国地质大学(武汉) | Indicate the hydrocarbon primary rock producing hydrocarbon process fluorescence in situ observation device of oil inclusions maturity |
CN108344721A (en) * | 2018-02-06 | 2018-07-31 | 中国地质大学(武汉) | Study the generation and expulsion modeling device of oil inclusions fluorescence color and its maturity relationship |
CN108344721B (en) * | 2018-02-06 | 2023-08-18 | 中国地质大学(武汉) | Hydrocarbon generation and discharge simulator for researching relationship between fluorescence color and maturity of oil inclusion |
CN108267434B (en) * | 2018-02-06 | 2023-08-29 | 中国地质大学(武汉) | In-situ fluorescence observation device for hydrocarbon source rock hydrocarbon production process for indicating maturity of oil inclusion |
CN110568149A (en) * | 2018-06-05 | 2019-12-13 | 中国石油化工股份有限公司 | Fine and rapid quantitative simulation method for hydrocarbon generation and discharge history of sedimentary basin hydrocarbon source rock |
CN110568149B (en) * | 2018-06-05 | 2021-07-30 | 中国石油化工股份有限公司 | Fine and rapid quantitative simulation method for hydrocarbon generation and discharge history of sedimentary basin hydrocarbon source rock |
CN110726655A (en) * | 2018-07-16 | 2020-01-24 | 中国石油化工股份有限公司 | Experimental method for simulating shale organic pore evolution process |
CN109100484A (en) * | 2018-07-31 | 2018-12-28 | 成都理工大学 | A kind of hydrocarbon history research method under thermal history and hydrocarbon thermal simulation constraint |
CN109100484B (en) * | 2018-07-31 | 2020-08-04 | 成都理工大学 | Hydrocarbon generation history research method under thermal history and hydrocarbon generation thermal simulation constraints |
CN110954969A (en) * | 2019-10-28 | 2020-04-03 | 中国石油大港油田勘探开发研究院 | Method for judging and identifying hydrocarbon generation period of ancient hydrocarbon source rock |
CN110954969B (en) * | 2019-10-28 | 2022-04-12 | 中国石油大港油田勘探开发研究院 | Method for judging and identifying hydrocarbon generation period of ancient hydrocarbon source rock |
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