[1]贾连凯,邱欣卫,肖张波,等.浅水多次波压制技术在珠江口盆地陆丰15洼缓坡带的应用[J].华南地震,2025,(04):126-135.[doi:10.13512/j.hndz.2025.04.17]
 JIA Liankai,QIU Xinwei,XIAO Zhangbo,et al.Application of Shallow Water Multiple Suppression Technology in Gentle Slope Zone of Lufeng 15 Depression in Pearl River Mouth Basin[J].,2025,(04):126-135.[doi:10.13512/j.hndz.2025.04.17]
点击复制

浅水多次波压制技术在珠江口盆地陆丰15洼缓坡带的应用()

华南地震[ISSN:1006-6977/CN:61-1281/TN]

卷:
期数:
2025年04期
页码:
126-135
栏目:
海洋地球物理
出版日期:
2025-11-30

文章信息/Info

Title:
Application of Shallow Water Multiple Suppression Technology in Gentle Slope Zone of Lufeng 15 Depression in Pearl River Mouth Basin
文章编号:
1001-8662(2025)04-0126-10
作者:
贾连凯12邱欣卫12肖张波12朱雯婷12赵 芳12胡求红12赵 越12
1.中海石油(中国)有限公司深圳分公司,深圳 518000;2.中海石油深海开发有限公司,深圳 518000
Author(s):
JIA Liankai12QIU Xinwei12XIAO Zhangbo12ZHU Wenting12ZHAO Fang12HU Qiuhong12ZHAO Yue12
1.Shenzhen Branch, CNOOC China Limited , Shenzhen 518000, China;2.CNOOC Deepwater Development Limited , Shenzhen 518000, China
关键词:
珠江口盆地浅水多次波陆丰15洼组合法
Keywords:
Pearl river mouth basinShallow water multiple waveLufeng 15 SagCombination method
分类号:
P67
DOI:
10.13512/j.hndz.2025.04.17
文献标志码:
A
摘要:
珠江口盆地陆丰凹陷地区水体相对较浅,地势相对平坦,该区珠江组地层普遍发育两套高速灰岩地层,海面、海底、灰岩层上下强烈的阻抗差形成的强反射系数界面极易形成较强能量的多次波,加之浅水地区形成的短周期多次波与有效反射混叠,导致浅中深地层均受到多次波影响,大大增加了地震解释的多解性。该区独特的地质特点导致多次波能量强、类型复杂,常规方法难以有效进行压制。基于该区地质特点,以盆地东部的陆丰15洼缓坡带为例,采用了针对性的浅水区组合多次波压制方法,即:首先使用基于水层模型的多次波消除法(MWD,ModelShallowWaterDemultiple)压制水层相关多次波尤其是短周期多次波,然后通过三维表面相关多次波衰减法(3DSRME,SurfaceRelatedMultipleElimination)压制水面相关长周期多次波尤其是与灰岩界面相关的多次波及部分层间多次波,最后在叠前时间偏移后共成像点道集上用高分辨率Radon变换压制残余多次波。研究结果表明:MWD+3DSRME+Radon串联组合法能够有效压制水层短周期多次波和灰岩界面相关的长周期多次波以及部分层间多次波等,显著提高了地震资料信噪比和成像质量,为类似地质背景的地区提供了重要的借鉴意义。
Abstract:
The water depth in Lufeng Sag of the Pearl River Mouth Basin is relatively shallow and the terrain is relatively flat. Two sets of high-velocity limestone strata are widely developed in the Pearl River Formation in this area. The strong reflection coefficient interfaces formed by the strong impedance difference between the sea surface, seafloor,and limestone strata readily generate multiples with high energy. In addition,the short-period multiples formed in shallow water areas interfere with effective reflections, affecting shallow, medium, and deep strata, which significantly increases the difficulty of seismic interpretation. The unique geological characteristics of this area result in strong multiple energy and complex multiple types, making it difficult to effectively suppress them by conventional methods. Based on the geological characteristics of the area,this study takes the gentle slope zone of Lufeng 15 Depression in the eastern part of the basin as an example and adopts a targeted combination multiple suppression approach for shallow water areas. First,the Model Shallow Water Demultiple(MWD)method is used to suppress water-layer-related multiples, especially short-period multiples. Then, the 3D Surface Related Multiple Elimination(3D SRME)method is applied to suppress long-period multiples related to the sea surface, particularly those associated with the limestone interface, as well as some interbed multiples. Finally, the high-resolution Radon transform is applied on common reflection point gathers to suppress residual multiples. The results show that the combined MWD + 3D SRME + Radon method can effectively suppress short-period water-layer multiples, long-period limestone-interface-related multiples, and some interbed multiples, significantly improving the signal-to-noise ratio and imaging quality of seismic data, and providing an important reference for areas with similar geological backgrounds.

参考文献/References:

[1]徐长贵,高阳东,刘军,等.南海东部富砂砾型大中型油气田发现与启示:以珠江口盆地惠州26洼古近系恩平组为例[J].石油勘探与开发,2024,51(1):1-14.
[2] Dragoset W H,Jerievi Z. Some remarks on surface multiple attenuation[J]. Geophysics,1998,63(2):772-789.
[3] Wang Y H. Multiple attenuation:coping with the spatial trun‐cation effect in the Radon transform domain[J]. Geophysical Prospecting,2010,51(1):75-87.
[4]胡天跃,王润秋,温书亮.聚束滤波法消除海上地震资料的多次波[J].石油地球物理勘探,2002,37(1):18?23.
[5]李列,谢玉洪,李志娜,等.海上多次波压制与成像方法研究进展[J].地球物理学进展,2015,30(1):446-453.
[6]孙海龙,王德利,陈鑫,等.基于波场延拓的多次波压制技术及其改进[J].世界地质,2015,34(1):226-231.
[7] Berkhout A J,Verschuur D J. Estimation of multiple scatter‐ing by iterative inversion,Part I:Theoretical considerations [J]. Geophysics,1997,62(5):1586-1595.
[8]张治忠,李三福,方中于,等. SWMA与SRME组合衰减自由界面多次波技术——在珠江口盆地A区的应用[J].物探化探计算技术,2016,38(2):8.
[9]杨佳佳,潘军,栾锡武,等.浅水多次波衰减技术在多道地震数据处理中的应用[J].海洋地质与第四纪地质,2020,40 (1):167-174.
[10]颜中辉,王小杰,刘媛媛,等.东海多次波压制的关键技术[J].海洋地质前沿,2020,36(7):64-72.
[11]李达,赵昌垒,刘巍,等.一种改进的DWD+SRME表面多次波组合法压制技术在南海西部浅水工区的应用[J].石油物探,2022,61(3):473-482.
[12]宋鑫.MWD算法实现及效率优化[J].中国石油和化工标准与质量,2023,43(04):102-104.
[13]郭梦秋,赵彦良,左胜杰,等.海上地震资料处理中的组合压制多次波技术[J].石油地球物理勘探,2012,47(4):537-544.
[14]贾连凯,吴时国,赵昌垒.多次波压制技术在南海北部陆缘深水区的应用[J].地球物理学进展,2014,29(2):920-930.
[15]王艳香,张军舵,王圣,等.分级多域迭代组合压制多次波技术[J].天然气地球科学,2014,25(2):243-251.
[16]曾华会,王孝,杨维,等.分级组合多次波压制技术——以玛湖地区为例[J].石油地球物理勘探,2018,53(2):13-19.
[17]贾连凯,张卫卫,肖张波,等.陆丰南珠江组下段#2370层岩性圈闭识别方法[J].海洋地质前沿,2023(11):36-49.
[18]彭光荣,庞雄奇,徐帜,等.珠江口盆地陆丰南地区古近系全油气系统特征与油气藏有序分布[J]. 地球科学, 2022,47(7):212-226.
[19]张向涛,汪旭东,舒誉,等.珠江口盆地陆丰凹陷大中型油田地质特征及形成条件[J].中南大学学报(自然科学版),2017,48(11):2979-2990.
[20]阙晓铭,雷永昌,张向涛,等.陆丰南地区断拗转换界面厘定及其地质意义[J].地质学报,2022,96(11):273-284.
[21]陈锋,朱筱敏,葛家旺,等.珠江口盆地陆丰南地区文昌组层序地层及沉积体系研究[J].岩性油气藏,2016,28 (4):67-77.
[22]孙阳子,于骏清,秦明静,等.陆丰X构造L1井钻后地质评价[J].石化技术,2023,30(2):94-96.
[23]陶宗普,丁放,何仕斌,等.陆丰凹陷T5地震反射层特征及其油气勘探意义[J].地学前缘,2009,16(4):182-189.
[24] Moore I,Bisley R. Multiple attenuation in shallow-water sit‐uation[C]// 68th EAGE Conference and Exhibition,Extend Abstracts,F018. Vienna,Austria:EAGE,2006.
[25]刘衡.海上地震资料多次波压制技术及应用研究[D].成都:西南石油大学,2014.
[26]施剑,刘江平,陈刚,等.陆架浅水区自由表面多次波压制方法[J].地球物理学进展,2017,32(2):902-910.
[27]彭海龙,任婷,赫建伟,等.基于水层建模理论的浅水多次波压制方法研究与应用[J]. 地球物理学进展,2016 (4):1646-1654.
[28]赵玥,徐秀刚,张浩楠,等.辽东湾海域浅水多次波组合压制技术[J].海洋地质前沿,2023,39(6):85-92.
[29]贺紫林,李振春,李志娜,等.基于反馈迭代模型的多次波压制方法综述[J].物探与化探,2022(2):275-284.
[30]王炜,徐强,徐爽.极浅水环境下的水层多次波分阶压制[J].工程地球物理学报,2022,19(5):683-688.
[31]李奇伟,邓小凡.高精度拉东变换技术在多次波压制中的应用[J].化工设计通讯,2020,46(3):83-97.
[32]陈泓竹,王彦春.频率域拉东变换加权约束反演压制层间多次波[J].石油地球物理勘探,2018,53(4):666-673.
[33]张明,肖张波,张志伟,等.组合多次波压制技术在陆丰凹陷陡坡带的应用[J].工程地球物理学报,2023,20(2):246-252.
[34]杨宏伟,谷丙洛,孔庆丰,等.基于最小二乘反演的各向异性逆时偏移角度域共成像点道集提取方法研究[J].地球物理学进展,2022(2):695-708.
[35]张振波,轩义华.高分辨率抛物线拉冬变换多次波压制技术[J].物探与化探,2014(5):981-988.

相似文献/References:

[1]吴琼玲,肖张波,雷永昌,等.珠江口盆地陆丰22洼岩浆活动地震响应及发育模式[J].华南地震,2023,(02):20.[doi:10.13512/j.hndz.2023.02.03]
 WU Qiongling,XIAO Zhangbo,LEI Yongchang,et al.Seismic Response and Development Model of Magmatic Activity in Lufeng 22 Sag,Pearl River Mouth Basin[J].,2023,(04):20.[doi:10.13512/j.hndz.2023.02.03]
[2]高永明,何理鹏,曲长伟,等.基于随钻电阻率成像测井分析的礁滩灰岩储层裂缝及次生溶蚀的精细表征——以珠江口盆地陆丰油田为例[J].华南地震,2024,(02):80.[doi:10.13512/j.hndz.2024.02.10]
 GAO Yongming,HE Lipeng,QU Changwei,et al.Fine Characterization of Fractures and Secondary Dissolution in Reef-Shoal Limestone Reservoirs Based on LWD Resistivity Imaging Logging Analysis—A Case Study of Lufeng Oilfield in the Pearl River Mouth Basin[J].,2024,(04):80.[doi:10.13512/j.hndz.2024.02.10]
[3]李克成,陈兆明,吕华星,等.珠江口盆地开平东地区断裂增强技术研究[J].华南地震,2026,46(02):115.[doi:10.13512/j.hndz.2026.02.15]
 LI Kecheng,CHEN Zhaoming,LYU Huaxing,et al.Research on Seismic Interpretation Processing Technology in the Kaiping East Region of the Pearl River Mouth Basin[J].,2026,46(04):115.[doi:10.13512/j.hndz.2026.02.15]

备注/Memo

备注/Memo:
收稿日期:2024-11-22
基金项目:中海石油(中国)有限公司深圳分公司生产性科研项目(SCKY-2024-SZ-YJYKT-07)
作者简介:贾连凯(1988-),男,硕士,工程师,研究方向为海洋地震资料处理、解释和反演研究。E-mail:cyy_jialk@126.com
更新日期/Last Update: 2025-11-30