WO2024099115A1 - Method and apparatus for creating seismic geosteering profile - Google Patents

Abstract

A method for creating a seismic geosteering profile, comprising: sequentially acquiring planar coordinate points of a vertical section and a build-up section of a horizontal well according to a drilling trajectory (101); on the basis of a preset seismic grid spacing, adjusting the positions and quantity of the planar coordinate points to obtain adjusted planar coordinate points (102); obtaining a target curve on the basis of the adjusted planar coordinate points and a preset drilling target, and determining intersection points between the target curve and lines of a seismic grid (103); determining a target seismic trace in the seismic grid on the basis of the intersection points (104); and obtaining a seismic geosteering profile on the basis of the target seismic trace (105). Also provided is an apparatus for creating a seismic geosteering profile. The present invention has the advantages of reducing the amount of calculation and the calculation time, rapidly and accurately obtaining an apparent stratigraphic dip to guide horizontal drilling, and improving the drilling encounter ratio.

Description

地震地质导向剖面的建立方法及装置Method and device for establishing seismic geological steering profile 技术领域Technical Field

本发明涉及地球物理勘探技术领域，具体地涉及一种地震地质导向剖面的建立方法、一种地震地质导向剖面的建立装置及一种机器可读存储介质。The present invention relates to the field of geophysical exploration technology, and in particular to a method for establishing a seismic geological steering profile, a device for establishing a seismic geological steering profile, and a machine-readable storage medium.

背景技术Background technique

随着三维地震勘探技术的不断进步和三维地震资料在油田勘探开发领域应用的不断深入，地震数据的重要性日益提高。在油田实施水平井钻进阶段，用地震数据的宏观趋势预测钻头前方地层倾角成为一种引导钻进的手段。当沿实钻井平面轨迹在三维深度域地震体中抽取地震剖面时，由于井眼轨迹方位角存在变化，可能因投影造成一定的误差，无法精准的获得地层视倾角，无法对钻头进行精准引导。With the continuous advancement of 3D seismic exploration technology and the deepening application of 3D seismic data in oilfield exploration and development, the importance of seismic data is increasing. In the stage of horizontal well drilling in oilfields, using the macro trend of seismic data to predict the formation dip in front of the drill bit has become a means of guiding drilling. When extracting seismic profiles in the 3D depth domain seismic volume along the actual drilling plane trajectory, due to the change in the azimuth of the wellbore trajectory, certain errors may be caused by projection, and it is impossible to accurately obtain the formation dip and accurately guide the drill bit.

发明内容Summary of the invention

本发明实施例的目的是提供一种地震地质导向剖面的建立方法及装置，该地震地质导向剖面的建立方法及装置用以解决上述的沿实钻井平面轨迹在三维深度域地震体中抽取地震剖面时，由于井眼轨迹方位角存在变化，可能因投影造成一定的误差，无法精准的获得地层视倾角，无法对钻头进行精准引导的问题。The purpose of an embodiment of the present invention is to provide a method and device for establishing a seismic geological steering profile. The method and device for establishing a seismic geological steering profile are used to solve the above-mentioned problem that when extracting a seismic profile in a three-dimensional depth domain seismic body along a real drilling plane trajectory, due to the change in the azimuth angle of the wellbore trajectory, certain errors may be caused by projection, and the formation apparent inclination cannot be accurately obtained, and the drill bit cannot be accurately guided.

为了实现上述目的，本发明实施例提供一种地震地质导向剖面的建立方法，包括：In order to achieve the above object, an embodiment of the present invention provides a method for establishing a seismic geological steering profile, comprising:

按钻井轨迹依次获取水平井垂直段和造斜段的平面坐标点；Obtain the plane coordinate points of the vertical section and the deflection section of the horizontal well in sequence according to the drilling trajectory;

基于预设地震网格间距，对所述平面坐标点的位置和数量进行调整，得到调整后的平面坐标点；Based on a preset seismic grid spacing, the positions and the number of the plane coordinate points are adjusted to obtain adjusted plane coordinate points;

基于调整后的平面坐标点和钻井预设靶点，得到目标曲线，并确定所述目标曲线与地震网格的测线的交点；Based on the adjusted plane coordinate points and the preset target points of the drilling, a target curve is obtained, and the intersection of the target curve and the survey line of the seismic grid is determined;

基于所述交点，在所述地震网格中确定目标地震道；Based on the intersection points, determining a target seismic trace in the seismic grid;

基于所述目标地震道，得到地震地质导向剖面。Based on the target seismic trace, a seismic geological steering profile is obtained.

可选的，所述基于预设地震网格间距，对所述平面坐标点的位置和数量进行调整，得到调整后的平面坐标点，包括： Optionally, adjusting the positions and the number of the plane coordinate points based on the preset seismic grid spacing to obtain the adjusted plane coordinate points includes:

获取相邻的平面坐标点之间的间距；Get the distance between adjacent plane coordinate points;

基于相邻的平面坐标点之间的间距与所述预设地震网格间距的大小关系，对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点。Based on the relationship between the spacing between adjacent plane coordinate points and the preset seismic grid spacing, the positions and number of the plane coordinate points are adjusted to obtain adjusted plane coordinate points.

可选的，所述基于相邻的平面坐标点之间的间距与预设地震网格间距的大小关系，对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点，包括：Optionally, adjusting the positions and number of the plane coordinate points based on the relationship between the spacing between adjacent plane coordinate points and the preset seismic grid spacing to obtain the adjusted plane coordinate points includes:

若相邻的平面坐标点之间的间距大于所述预设地震网格间距，则基于第一预设规则对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点；If the spacing between adjacent plane coordinate points is greater than the preset seismic grid spacing, adjusting the positions and number of the plane coordinate points based on the first preset rule to obtain adjusted plane coordinate points;

若相邻的平面坐标点之间的间距小于所述预设地震网格间距，则基于第二预设规则对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点。If the spacing between adjacent plane coordinate points is smaller than the preset seismic grid spacing, the positions and the number of the plane coordinate points are adjusted based on the second preset rule to obtain adjusted plane coordinate points.

可选的，所述基于第一预设规则对平面坐标点的位置进行调整，得到调整后的平面坐标点，包括：Optionally, adjusting the position of the plane coordinate point based on the first preset rule to obtain the adjusted plane coordinate point includes:

将相邻的平面坐标点中次序较小的平面坐标点确定为初始坐标点；Determine the plane coordinate point with the smaller order among the adjacent plane coordinate points as the initial coordinate point;

在所述初始坐标点与下一相邻平面坐标点之间确定出与所述初始坐标点间距为预设地震网格间距的目标坐标点，将该目标坐标点作为调整后的平面坐标点。A target coordinate point whose distance from the initial coordinate point is a preset seismic grid distance is determined between the initial coordinate point and the next adjacent plane coordinate point, and the target coordinate point is used as the adjusted plane coordinate point.

可选的，所述基于第二预设规则对平面坐标点的位置进行调整，得到调整后的平面坐标点，包括：Optionally, adjusting the position of the plane coordinate point based on the second preset rule to obtain the adjusted plane coordinate point includes:

将相邻的平面坐标点中次序较小的平面坐标点确定为初始坐标点；Determine the plane coordinate point with the smaller order among the adjacent plane coordinate points as the initial coordinate point;

在所述初始坐标点与下一相邻平面坐标点之间的延长线上确定出与所述初始坐标点间距为预设地震网格间距的目标坐标点，舍弃该目标坐标点与所述初始坐标点之间的所有平面坐标点，并将该目标坐标点确定为所述调整后的平面坐标点。A target coordinate point is determined on an extension line between the initial coordinate point and the next adjacent plane coordinate point, the distance between the target coordinate point and the initial coordinate point being a preset seismic grid distance, all plane coordinate points between the target coordinate point and the initial coordinate point are discarded, and the target coordinate point is determined as the adjusted plane coordinate point.

可选的，所述基于所述交点，在所述地震网格中确定目标地震道，包括：Optionally, determining a target seismic trace in the seismic grid based on the intersection point includes:

对每一交点：For each intersection point:

在所述地震网格中，将距离交点最近的地震道确定为所述目标地震道。In the seismic grid, the seismic trace closest to the intersection point is determined as the target seismic trace.

可选的，所述基于所述目标地震道，得到地震地质导向剖面，包括：Optionally, obtaining a seismic geosteering profile based on the target seismic trace includes:

基于所述目标地震道，构建地震剖面图；constructing a seismic profile based on the target seismic trace;

确定地震剖面图中每一目标地震道的地震道属性参数；Determine the seismic trace attribute parameters of each target seismic trace in the seismic profile;

基于相邻的目标地震道之间的地震道属性参数，计算得到沿钻井轨迹的地层视倾角； Based on the seismic trace attribute parameters between adjacent target seismic traces, the apparent dip angle of the formation along the drilling trajectory is calculated;

基于所述地层视倾角，得到地震地质导向剖面。Based on the formation apparent dip angle, a seismic geosteering profile is obtained.

可选的，所述地震道属性参数为振幅波峰、振幅波谷和过零点中的任一种。Optionally, the seismic trace attribute parameter is any one of an amplitude peak, an amplitude trough and a zero crossing point.

可选的，所述基于相邻的目标地震道之间的地震道属性参数，计算得到沿钻井轨迹的地层视倾角，包括：Optionally, the calculating of the apparent dip angle of the formation along the drilling trajectory based on the seismic trace attribute parameters between adjacent target seismic traces includes:

采用以下计算公式计算得到地层视倾角：
The formation apparent dip angle is calculated using the following formula:

其中，A为地层视倾角；H为相邻的目标地震道的振幅波峰或振幅波谷或过零点之间的高差；L为相邻的目标地震道之间的距离。Wherein, A is the apparent dip of the formation; H is the height difference between the amplitude peaks or amplitude troughs or zero-crossing points of adjacent target seismic traces; and L is the distance between adjacent target seismic traces.

本发明实施例还提供一种地震地质导向剖面的建立装置，包括：The embodiment of the present invention further provides a device for establishing a seismic geological steering profile, comprising:

获取模块，用于按钻井轨迹依次获取水平井垂直段和造斜段的平面坐标点；An acquisition module is used to sequentially acquire the plane coordinate points of the vertical section and the deflection section of the horizontal well according to the drilling trajectory;

调整模块，用于基于预设地震网格间距，对所述平面坐标点进行调整，得到调整后的平面坐标点；An adjustment module, used for adjusting the plane coordinate points based on a preset seismic grid spacing to obtain adjusted plane coordinate points;

第一确定模块，用于基于调整后的平面坐标点和钻井预设靶点，得到目标曲线，并确定所述目标曲线与地震网格的测线的交点；A first determination module is used to obtain a target curve based on the adjusted plane coordinate points and the preset drilling target points, and determine the intersection of the target curve and the survey line of the seismic grid;

第二确定模块，用于基于所述交点，在所述地震网格中确定目标地震道；A second determination module, configured to determine a target seismic trace in the seismic grid based on the intersection point;

第三确定模块，用于基于所述目标地震道，得到地震地质导向剖面。The third determination module is used to obtain a seismic geological steering profile based on the target seismic trace.

另一方面，本发明提供一种机器可读存储介质，该机器可读存储介质上存储有指令，该指令用于使得机器执行本申请上述的地震地质导向剖面的建立方法。On the other hand, the present invention provides a machine-readable storage medium having instructions stored thereon, the instructions being used to enable a machine to execute the method for establishing a seismic geological steering profile described above in the present application.

本技术方案在获取水平井垂直段和造斜段的平面坐标点后对平面坐标点的数量和位置进行调整，能够降低计算量和计算时间；另外严格遵循钻井井眼轨迹方位角的变化，准确获取地震道数据，能够快速、准确的得到地层视倾角，指导水平钻井钻进，提高钻遇率。This technical solution adjusts the number and position of the plane coordinate points of the vertical section and the inclined section of the horizontal well after obtaining them, which can reduce the amount of calculation and calculation time; in addition, it strictly follows the changes in the azimuth of the drilling well trajectory and accurately obtains seismic data, which can quickly and accurately obtain the apparent dip angle of the formation, guide horizontal drilling, and improve the drilling rate.

本发明实施例的其它特征和优点将在随后的具体实施方式部分予以详细说明。Other features and advantages of the embodiments of the present invention will be described in detail in the subsequent detailed description.

附图说明BRIEF DESCRIPTION OF THE DRAWINGS

附图是用来提供对本发明实施例的进一步理解，并且构成说明书的一部分，与下面的具体实施方式一起用于解释本发明实施例，但并不构成对本发明实施例的限制。在附图中： The accompanying drawings are used to provide a further understanding of the embodiments of the present invention and constitute a part of the specification. Together with the following specific embodiments, they are used to explain the embodiments of the present invention, but do not constitute a limitation on the embodiments of the present invention. In the accompanying drawings:

附图是用来提供对本发明实施例的进一步理解，并且构成说明书的一部分，与下面的具体实施方式一起用于解释本发明实施例，但并不构成对本发明实施例的限制。在附图中：The accompanying drawings are used to provide a further understanding of the embodiments of the present invention and constitute a part of the specification. Together with the following specific embodiments, they are used to explain the embodiments of the present invention, but do not constitute a limitation on the embodiments of the present invention. In the accompanying drawings:

图1是本发明提供的地震地质导向剖面的建立方法的流程图；FIG1 is a flow chart of a method for establishing a seismic geosteering profile provided by the present invention;

图2是本发明提供的常规空间水平井轨迹导向剖面投影示意图；FIG2 is a schematic diagram of a conventional spatial horizontal well trajectory guidance cross-sectional projection provided by the present invention;

图3是本发明提供的水平井垂直段及造斜段轨迹平面位置示意图；3 is a schematic diagram of the plane position of the trajectory of the vertical section and the deflection section of the horizontal well provided by the present invention;

图4是本发明提供的水平井垂直段及造斜段轨迹按预设地震网格间距调整后的平面位置示意图；4 is a schematic diagram of the plane position of the vertical section and the deflection section trajectory of the horizontal well provided by the present invention after being adjusted according to the preset seismic grid spacing;

图5是本发明提供的图3中增加钻井预设靶点后的轨迹坐标图；FIG5 is a trajectory coordinate diagram after adding a preset drilling target point in FIG3 provided by the present invention;

图6是本发明提供的沿钻井轨迹的直线段获取的地震数据的位置示意图；FIG6 is a schematic diagram of the location of seismic data obtained along a straight line segment of a drilling trajectory provided by the present invention;

图7是本发明提供的沿钻井轨迹获取的三维深度域地震剖面示意图；7 is a schematic diagram of a three-dimensional depth domain seismic profile obtained along a drilling trajectory provided by the present invention;

图8是本发明提供的基于地层视倾角得到的地震地质导向剖面示意图；FIG8 is a schematic diagram of a seismic geosteering profile obtained based on the apparent dip angle of the formation provided by the present invention;

图9是本发明提供的地震地质导向剖面三维显示图；FIG9 is a three-dimensional display diagram of the seismic geosteering profile provided by the present invention;

图10是本发明提供的地震地质导向剖面的建立装置的结构示意图。FIG. 10 is a schematic structural diagram of the device for establishing a seismic geological steering profile provided by the present invention.

附图标记说明
1-获取模块；           2-调整模块；        3-第一确定模块；
4-第二确定模块；       5-第三确定模块。Description of Reference Numerals
1-acquisition module; 2-adjustment module; 3-first determination module;
4- the second determination module; 5- the third determination module.

具体实施方式Detailed ways

以下结合附图对本发明实施例的具体实施方式进行详细说明。应当理解的是，此处所描述的具体实施方式仅用于说明和解释本发明实施例，并不用于限制本发明实施例。The specific implementation of the embodiment of the present invention is described in detail below in conjunction with the accompanying drawings. It should be understood that the specific implementation described here is only used to illustrate and explain the embodiment of the present invention, and is not used to limit the embodiment of the present invention.

本申请中的术语“第一”、“第二”等是用于区分不同对象，而非用于描述特定顺序。同时，术语“包括”及其任何形式的变形，意图在于覆盖不排他的包含。The terms "first", "second", etc. in this application are used to distinguish different objects rather than to describe a specific order. At the same time, the term "include" and any form of its variation are intended to cover non-exclusive inclusions.

本申请实施例提供一种待转注老井使用年限预估方法、装置、电子设备和计算机可读存储介质。The embodiments of the present application provide a method, device, electronic device and computer-readable storage medium for estimating the useful life of an old well to be re-injected.

其中，该装置具体可以集成在计算机设备中，该电子设备可以为终端、服务器等设备。其中，终端可以为手机、平板电脑、智能蓝牙设备、笔记本电脑、或者个人电脑(Personal Computer，PC)等设备；服务器可以是单一服务器，也可以是由多个服务器组成的服务器集群。 The device can be integrated into a computer device, and the electronic device can be a terminal, a server, etc. The terminal can be a mobile phone, a tablet computer, a smart Bluetooth device, a laptop, or a personal computer (PC), etc. The server can be a single server or a server cluster composed of multiple servers.

在一些实施例中，该装置还可以集成在多个电子设备中，比如，所述装置可以集成在多个服务器中，由多个服务器来实现本申请的方法。In some embodiments, the device may also be integrated into multiple electronic devices. For example, the device may be integrated into multiple servers, and the method of the present application may be implemented by multiple servers.

在一些实施例中，服务器也可以以终端的形式来实现。In some embodiments, the server may also be implemented in the form of a terminal.

以下分别进行详细说明。需说明的是，以下实施例的序号不作为对实施例优选顺序的限定。It should be noted that the serial numbers of the following embodiments are not intended to limit the preferred order of the embodiments.

图1是本发明提供的地震地质导向剖面的建立方法的流程图；图2是本发明提供的常规空间水平井轨迹导向剖面投影示意图；图3是本发明提供的水平井垂直段及造斜段轨迹平面位置示意图；图4是本发明提供的水平井垂直段及造斜段轨迹按预设地震网格间距调整后的平面位置示意图；图5是本发明提供的图3中增加钻井预设靶点后的轨迹坐标图；图6是本发明提供的沿钻井轨迹的直线段获取的地震数据的位置示意图；图7是本发明提供的沿钻井轨迹获取的三维深度域地震剖面示意图；图8是本发明提供的基于地层视倾角得到的地震地质导向剖面示意图；图9是本发明提供的地震地质导向剖面三维显示图；图10是本发明提供的地震地质导向剖面的建立装置的结构示意图。Fig. 1 is a flow chart of the method for establishing a seismic geological steering profile provided by the present invention; Fig. 2 is a schematic diagram of the projection of the conventional spatial horizontal well trajectory steering profile provided by the present invention; Fig. 3 is a schematic diagram of the plane position of the trajectory of the vertical section and the inclined section of the horizontal well provided by the present invention; Fig. 4 is a schematic diagram of the plane position of the trajectory of the vertical section and the inclined section of the horizontal well provided by the present invention after adjustment according to the preset seismic grid spacing; Fig. 5 is a trajectory coordinate diagram after adding a preset drilling target point in Fig. 3 provided by the present invention; Fig. 6 is a schematic diagram of the position of seismic data obtained along the straight line segment of the drilling trajectory provided by the present invention; Fig. 7 is a schematic diagram of the three-dimensional depth domain seismic profile obtained along the drilling trajectory provided by the present invention; Fig. 8 is a schematic diagram of the seismic geological steering profile obtained based on the apparent dip angle of the formation provided by the present invention; Fig. 9 is a three-dimensional display diagram of the seismic geological steering profile provided by the present invention; and Fig. 10 is a structural schematic diagram of the device for establishing a seismic geological steering profile provided by the present invention.

如图1所示，本实施例提供一种地震地质导向剖面的建立方法，包括：As shown in FIG1 , this embodiment provides a method for establishing a seismic geosteering profile, comprising:

步骤101、按钻井轨迹依次获取水平井垂直段和造斜段的平面坐标点；Step 101, sequentially obtaining the plane coordinate points of the vertical section and the deflection section of the horizontal well according to the drilling trajectory;

步骤102、基于预设地震网格间距，对所述平面坐标点的位置和数量进行调整，得到调整后的平面坐标点；Step 102: Based on the preset seismic grid spacing, the positions and the number of the plane coordinate points are adjusted to obtain adjusted plane coordinate points;

步骤103、基于调整后的平面坐标点和钻井预设靶点，得到目标曲线，并确定所述目标曲线与地震网格的测线的交点；Step 103: obtaining a target curve based on the adjusted plane coordinate points and the preset target points of the drilling, and determining the intersection of the target curve and the survey line of the seismic grid;

步骤104、基于所述交点，在所述地震网格中确定目标地震道；Step 104: determining a target seismic trace in the seismic grid based on the intersection point;

步骤105、基于所述目标地震道，得到地震地质导向剖面。Step 105: Obtain a seismic geological steering profile based on the target seismic trace.

具体地，在进行地质钻井的过程中，首先根据探测的结果在地层中确定钻井预设靶点，钻井预设靶点的数量根据实际的钻井情况确定，在正式钻井时，基于确定的水平井井口位置依次向钻井预设靶点钻进，形成水平井的垂直段和造斜段，基于水平井的位置构建出地面坐标系，并得到水平井的垂直段和造斜段在地面坐标系中的平面坐标点，该地面坐标系的坐标轴分别指向东南西北方向，以准确确定出水平井的垂直段和造斜段在平面坐标点中的位置，水平井的垂直段和造斜段在地面坐标系中的平面坐标点可以理解为是水平井在地面坐标系中的投影中的点位，如图2所示，将三维空间的水平井的垂直段和造斜段按照设定间距投影在地面坐标系中，并在地面坐标系中得到平面坐标点，如图3所示，但是，由于水平井的垂直段和造斜段存在垂向上的间距差别，导致部分位置的平面坐标点过密或过疏，若平面坐标点过密，平面坐标点之间的间距小于预设地震网格间距，按 此坐标点提取地震道数据不仅造成取道重复，还会增加计算量和计算时间，因此需要基于预设地震网格间距对所述平面坐标点的位置和数量进行调整，得到调整后的平面坐标点，调整后的平面坐标点之间间距较为均匀，如图4所示；若平面坐标点过疏，平面坐标点之间的间距大于预设地震网格间距，按此坐标点提取地震道数据会造成取道不完整，导致地震道数据缺失，因此需要基于预设地震网格间距对所述平面坐标点的位置和数量进行调整，得到调整后的平面坐标点，调整后的平面坐标点之间间距较为均匀；依次连接调后的平面坐标点和钻井预设靶点，能够得到目标曲线，如图5所示，并该目标曲线与地震网格的测线之间的交点更加清晰；再基于确定的所述交点，在所述地震网格中确定目标地震道；基于所述目标地震道，得到地震地质导向剖面。总体来说，通过上述方案能够减少并保证水平井垂直段和造斜段的平面坐标点更均匀的分布，从而减少计算时的数据量，同时能够保证基于调整后的平面坐标点和钻井预设靶点，得到的目标曲线与地震网格的测线的交点更加清晰和精准，再通过得到的交点，在所述地震网格中确定目标地震道，从而得到地震地质导向剖面，准确指导水平钻井钻进，提高钻遇率。Specifically, in the process of geological drilling, firstly, preset drilling target points are determined in the formation according to the detection results. The number of preset drilling target points is determined according to the actual drilling situation. During the formal drilling, based on the determined wellhead position of the horizontal well, drilling is carried out in sequence toward the preset drilling target points to form the vertical section and the inclined section of the horizontal well. A ground coordinate system is constructed based on the position of the horizontal well, and the plane coordinate points of the vertical section and the inclined section of the horizontal well in the ground coordinate system are obtained. The coordinate axes of the ground coordinate system point to the southeast, northwest, and northeast directions respectively, so as to accurately determine the vertical section and the inclined section of the horizontal well in the plane coordinate system. The position of the punctuation mark, the plane coordinate points of the vertical section and the deflection section of the horizontal well in the ground coordinate system can be understood as the point position in the projection of the horizontal well in the ground coordinate system, as shown in Figure 2. The vertical section and the deflection section of the horizontal well in three-dimensional space are projected in the ground coordinate system according to the set spacing, and the plane coordinate points are obtained in the ground coordinate system, as shown in Figure 3. However, due to the vertical spacing difference between the vertical section and the deflection section of the horizontal well, the plane coordinate points of some positions are too dense or too sparse. If the plane coordinate points are too dense, the spacing between the plane coordinate points is less than the preset seismic grid spacing, according to Extracting seismic trace data from this coordinate point will not only cause repeated routing, but also increase the amount of calculation and computing time. Therefore, it is necessary to adjust the position and number of the plane coordinate points based on the preset seismic grid spacing to obtain the adjusted plane coordinate points, and the spacing between the adjusted plane coordinate points is relatively uniform, as shown in Figure 4; if the plane coordinate points are too sparse, the spacing between the plane coordinate points is greater than the preset seismic grid spacing, extracting seismic trace data according to this coordinate point will cause incomplete routing, resulting in missing seismic trace data. Therefore, it is necessary to adjust the position and number of the plane coordinate points based on the preset seismic grid spacing to obtain the adjusted plane coordinate points, and the spacing between the adjusted plane coordinate points is relatively uniform; by sequentially connecting the adjusted plane coordinate points and the preset target points of the drilling, the target curve can be obtained, as shown in Figure 5, and the intersection between the target curve and the survey line of the seismic grid is clearer; then based on the determined intersection, the target seismic trace is determined in the seismic grid; based on the target seismic trace, the seismic geological guidance profile is obtained. In general, the above scheme can reduce and ensure a more uniform distribution of the plane coordinate points of the vertical section and the inclined section of the horizontal well, thereby reducing the amount of data during calculation. At the same time, it can ensure that the intersection of the target curve and the survey line of the seismic grid obtained based on the adjusted plane coordinate points and the preset drilling target points is clearer and more accurate. Then, the target seismic trace is determined in the seismic grid through the obtained intersection, thereby obtaining a seismic geological steering profile, accurately guiding the horizontal drilling, and improving the drilling rate.

进一步地，所述基于预设地震网格间距，对所述平面坐标点的位置和数量进行调整，得到调整后的平面坐标点，包括：Furthermore, the position and number of the plane coordinate points are adjusted based on the preset seismic grid spacing to obtain the adjusted plane coordinate points, including:

获取相邻的平面坐标点之间的间距；Get the distance between adjacent plane coordinate points;

基于相邻的平面坐标点之间的间距与所述预设地震网格间距的大小关系，对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点。Based on the relationship between the spacing between adjacent plane coordinate points and the preset seismic grid spacing, the positions and number of the plane coordinate points are adjusted to obtain adjusted plane coordinate points.

具体地，预设地震网格间距可根据实际的地震数据进行分析得到，从而选取最佳的地震网格间距作为最佳的预设地震网格间距，在对所述平面坐标点的位置和数量进行调整时，首先确定相邻的平面坐标点之间的间距，并将确定的预设地震网格间距与相邻的平面坐标点之间的间距进行比较判断，并根据比较情况进行位置和数量调整，得到调整后的平面坐标点。Specifically, the preset seismic grid spacing can be obtained by analyzing the actual seismic data, so as to select the optimal seismic grid spacing as the optimal preset seismic grid spacing. When adjusting the position and number of the plane coordinate points, first determine the spacing between adjacent plane coordinate points, and compare and judge the determined preset seismic grid spacing with the spacing between adjacent plane coordinate points, and adjust the position and quantity according to the comparison to obtain the adjusted plane coordinate points.

进一步地，所述基于相邻的平面坐标点之间的间距与预设地震网格间距的大小关系，对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点，包括：Furthermore, the position and number of the plane coordinate points are adjusted based on the size relationship between the spacing between adjacent plane coordinate points and the preset seismic grid spacing to obtain the adjusted plane coordinate points, including:

若相邻的平面坐标点之间的间距大于所述预设地震网格间距，则基于第一预设规则对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点；If the spacing between adjacent plane coordinate points is greater than the preset seismic grid spacing, adjusting the positions and number of the plane coordinate points based on the first preset rule to obtain adjusted plane coordinate points;

若相邻的平面坐标点之间的间距小于所述预设地震网格间距，则基于第二预设规则对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点。If the spacing between adjacent plane coordinate points is smaller than the preset seismic grid spacing, the positions and the number of the plane coordinate points are adjusted based on the second preset rule to obtain adjusted plane coordinate points.

具体地，比较预设地震网格间距与相邻的平面坐标点之间的间距，能够确定出三种情况，即：相邻的平面坐标点之间的间距与预设地震网格间距相等、相邻的平面坐标点之间的间距大于预设地震网格间距、相邻的平面坐标点之间的间距 小于预设地震网格间距。其中，若相邻的平面坐标点之间的间距与预设地震网格间距相等，此情况下不进行调整，将相邻的两个平面坐标点确认为调整后的平面坐标点，继续进行后续的判断；若相邻的平面坐标点之间的间距大于预设地震网格间距，则说明相邻的平面坐标点之间的间距过疏，相邻的平面坐标点之间确定的地震道数据相应减少，会降低数据的精度，因此，在本实施方式中，通过第一预设规则对平面坐标点的位置和数量进行调整，使得平面坐标点分布更加均匀；若相邻的平面坐标点之间的间距小于预设地震网格间距，则说明相邻的平面坐标点之间的间距过密，相邻的平面坐标点之间确定的地震道数据相应过多，造成重复取道，无形中增加了计算量且对解雇的精度度毫无帮助，因此，在本实施方式中，通过第二预设规则对平面坐标点的位置和数量进行调整，使得平面坐标点分布更加均匀。Specifically, by comparing the preset seismic grid spacing with the spacing between adjacent plane coordinate points, three situations can be determined, namely: the spacing between adjacent plane coordinate points is equal to the preset seismic grid spacing, the spacing between adjacent plane coordinate points is greater than the preset seismic grid spacing, and the spacing between adjacent plane coordinate points is greater than the preset seismic grid spacing. Less than the preset seismic grid spacing. Among them, if the spacing between adjacent plane coordinate points is equal to the preset seismic grid spacing, no adjustment is made in this case, and the two adjacent plane coordinate points are confirmed as adjusted plane coordinate points, and subsequent judgments are continued; if the spacing between adjacent plane coordinate points is greater than the preset seismic grid spacing, it means that the spacing between adjacent plane coordinate points is too sparse, and the seismic trace data determined between adjacent plane coordinate points is correspondingly reduced, which will reduce the accuracy of the data. Therefore, in this embodiment, the position and number of plane coordinate points are adjusted by the first preset rule, so that the plane coordinate points are distributed more evenly; if the spacing between adjacent plane coordinate points is less than the preset seismic grid spacing, it means that the spacing between adjacent plane coordinate points is too dense, and the seismic trace data determined between adjacent plane coordinate points is correspondingly too much, resulting in repeated paths, which invisibly increases the amount of calculation and is of no help to the accuracy of the dismissal. Therefore, in this embodiment, the position and number of plane coordinate points are adjusted by the second preset rule, so that the plane coordinate points are distributed more evenly.

进一步地，所述基于第一预设规则对平面坐标点的位置进行调整，得到调整后的平面坐标点，包括：Further, the adjusting the position of the plane coordinate point based on the first preset rule to obtain the adjusted plane coordinate point includes:

将相邻的平面坐标点中次序较小的平面坐标点确定为初始坐标点；Determine the plane coordinate point with the smaller order among the adjacent plane coordinate points as the initial coordinate point;

在所述初始坐标点与下一相邻平面坐标点之间确定出与所述初始坐标点间距为预设地震网格间距的目标坐标点，将该目标坐标点作为调整后的平面坐标点。A target coordinate point whose distance from the initial coordinate point is a preset seismic grid distance is determined between the initial coordinate point and the next adjacent plane coordinate point, and the target coordinate point is used as the adjusted plane coordinate point.

具体地，在本实施方式中，若判断出相邻的平面坐标点之间的间距大于预设地震网格间距，则将相邻的平面坐标点中次序较小的平面坐标点确定为初始坐标点，并在初始坐标点与下一相邻平面坐标点之间确定出与初始坐标点间距为预设地震网格间距的目标坐标点，将该目标坐标点作为调整后的平面坐标点。由于平面坐标点已按钻井轨迹进行排序，因此，再将该调整后的平面坐标点与相邻的下一平面坐标点进行比较，若该调整后的平面坐标点与相邻的下一平面坐标点之间的间距仍然大于预设地震网格间距，则采取上述的方法(第一预设规则)继续进行调整，若该调整后的平面坐标点与相邻的下一平面坐标点之间的间距仍然小于预设地震网格间距，则采取第二预设规则进行调整，使得平面坐标点分布更加均匀，直至对所有坐标点进行调整。Specifically, in this embodiment, if it is determined that the spacing between adjacent plane coordinate points is greater than the preset seismic grid spacing, the plane coordinate point with a smaller order among the adjacent plane coordinate points is determined as the initial coordinate point, and a target coordinate point whose spacing with the initial coordinate point is the preset seismic grid spacing is determined between the initial coordinate point and the next adjacent plane coordinate point, and the target coordinate point is used as the adjusted plane coordinate point. Since the plane coordinate points have been sorted according to the drilling trajectory, the adjusted plane coordinate point is compared with the next adjacent plane coordinate point. If the spacing between the adjusted plane coordinate point and the next adjacent plane coordinate point is still greater than the preset seismic grid spacing, the above method (first preset rule) is adopted to continue to adjust. If the spacing between the adjusted plane coordinate point and the next adjacent plane coordinate point is still less than the preset seismic grid spacing, the second preset rule is adopted to adjust so that the plane coordinate points are distributed more evenly until all coordinate points are adjusted.

其中，再将该调整后的平面坐标点与相邻的下一平面坐标点进行比较后，若该调整后的平面坐标点与相邻的下一平面坐标点之间的间距与预设地震网格间距相等，此情况下不进行调整，直接将相邻的下一平面坐标点确定为新的目标坐标点，并将该目标坐标点作为调整后的平面坐标点。Among them, after comparing the adjusted plane coordinate point with the adjacent next plane coordinate point, if the spacing between the adjusted plane coordinate point and the adjacent next plane coordinate point is equal to the preset seismic grid spacing, no adjustment is made in this case, and the adjacent next plane coordinate point is directly determined as the new target coordinate point, and the target coordinate point is used as the adjusted plane coordinate point.

进一步地，所述基于第二预设规则对平面坐标点的位置进行调整，得到调整后的平面坐标点，包括：Further, the adjusting the position of the plane coordinate point based on the second preset rule to obtain the adjusted plane coordinate point includes:

将相邻的平面坐标点中次序较小的平面坐标点确定为初始坐标点； Determine the plane coordinate point with the smaller order among the adjacent plane coordinate points as the initial coordinate point;

在所述初始坐标点与下一相邻平面坐标点之间的延长线上确定出与所述初始坐标点间距为预设地震网格间距的目标坐标点，舍弃该目标坐标点与所述初始坐标点之间的所有平面坐标点，并将该目标坐标点确定为所述调整后的平面坐标点。A target coordinate point is determined on an extension line between the initial coordinate point and the next adjacent plane coordinate point, the distance between the target coordinate point and the initial coordinate point being a preset seismic grid distance, all plane coordinate points between the target coordinate point and the initial coordinate point are discarded, and the target coordinate point is determined as the adjusted plane coordinate point.

在本实施方式中，若判断出相邻的平面坐标点之间的间距小于预设地震网格间距，同样将相邻的平面坐标点中次序较小的平面坐标点确定为初始坐标点，并在初始坐标点与下一相邻平面坐标点之间的延长线上确定出与初始坐标点间距为预设地震网格间距的目标坐标点，舍弃该目标坐标点与所述初始坐标点之间的所有平面坐标点，并将该目标坐标点确定为调整后的平面坐标点。由于平面坐标点已按钻井轨迹进行排序，因此，再将该调整后的平面坐标点与相邻的下一平面坐标点进行比较，若该调整后的平面坐标点与相邻的下一平面坐标点之间的间距大于预设地震网格间距，则采取上述的第一预设规则继续进行调整，若该调整后的平面坐标点与相邻的下一平面坐标点之间的间距仍然小于预设地震网格间距，则采取第二预设规则进行调整，使得平面坐标点分布更加均匀，直至对所有坐标点进行调整。In this embodiment, if it is determined that the spacing between adjacent plane coordinate points is less than the preset seismic grid spacing, the plane coordinate point with a smaller order among the adjacent plane coordinate points is also determined as the initial coordinate point, and a target coordinate point whose spacing from the initial coordinate point is the preset seismic grid spacing is determined on the extension line between the initial coordinate point and the next adjacent plane coordinate point, all plane coordinate points between the target coordinate point and the initial coordinate point are discarded, and the target coordinate point is determined as the adjusted plane coordinate point. Since the plane coordinate points have been sorted according to the drilling trajectory, the adjusted plane coordinate point is compared with the next adjacent plane coordinate point. If the spacing between the adjusted plane coordinate point and the next adjacent plane coordinate point is greater than the preset seismic grid spacing, the above-mentioned first preset rule is adopted to continue the adjustment. If the spacing between the adjusted plane coordinate point and the next adjacent plane coordinate point is still less than the preset seismic grid spacing, the second preset rule is adopted to adjust so that the plane coordinate points are distributed more evenly until all coordinate points are adjusted.

另外，初始坐标点与下一相邻平面坐标点之间的延长线的方向可根据平面坐标点的位置进行确定。In addition, the direction of the extension line between the initial coordinate point and the next adjacent plane coordinate point can be determined according to the position of the plane coordinate point.

进一步地，所述基于所述交点，在所述地震网格中确定目标地震道，包括：Further, determining a target seismic trace in the seismic grid based on the intersection point includes:

对每一交点：For each intersection point:

在所述地震网格中，将距离交点最近的地震道确定为所述目标地震道。In the seismic grid, the seismic trace closest to the intersection point is determined as the target seismic trace.

具体地，如图6所示，在基于预设地震网格间距，对所述平面坐标点的位置和数量进行调整，得到调整后的平面坐标点后，为了指导钻进，则沿当前的钻井轨迹朝着钻井预设靶点钻进，能够得到目标曲线，该目标曲线为完整的沿井剖面任意线，其与地震网格存在交点，因此，可以针对每一交点，获取距离交点最近的地震道为目标地震道，用于在后续形成地震剖面。Specifically, as shown in Figure 6, based on the preset seismic grid spacing, the position and number of the plane coordinate points are adjusted. After the adjusted plane coordinate points are obtained, in order to guide drilling, drilling is carried out along the current drilling trajectory toward the preset drilling target point, and a target curve can be obtained. The target curve is a complete arbitrary line along the well profile, which has an intersection with the seismic grid. Therefore, for each intersection, the seismic trace closest to the intersection can be obtained as the target seismic trace, which is used to form the seismic profile later.

进一步地，所述基于所述目标地震道，得到地震地质导向剖面，包括：Furthermore, obtaining a seismic geological steering profile based on the target seismic trace includes:

基于所述目标地震道，构建地震剖面图；constructing a seismic profile based on the target seismic trace;

确定地震剖面图中每一目标地震道的地震道属性参数；Determine the seismic trace attribute parameters of each target seismic trace in the seismic profile;

基于相邻的目标地震道之间的地震道属性参数，计算得到沿钻井轨迹的地层视倾角；Based on the seismic trace attribute parameters between adjacent target seismic traces, the apparent dip angle of the formation along the drilling trajectory is calculated;

基于所述地层视倾角，得到地震地质导向剖面。Based on the formation apparent dip angle, a seismic geological steering profile is obtained.

进一步地，所述地震道属性参数为振幅波峰、振幅波谷和过零点中的任一种。 Furthermore, the seismic trace attribute parameter is any one of an amplitude peak, an amplitude trough and a zero crossing point.

具体地，如图7-9所示，在获取到目标地震道后，基于目标地震道构建地震剖面图(构建地震构面图为现有技术，此处不再赘述)，并能够在地震剖面图中确定出每一目标地震道的地震道属性参数；再基于相邻的目标地震道之间的地震道属性参数，计算得到沿钻井轨迹的地层视倾角；基于计算得到的多个地层视倾角，便得到地震地质导向剖面。Specifically, as shown in Figures 7-9, after acquiring the target seismic traces, a seismic profile is constructed based on the target seismic traces (constructing seismic profiles is a prior art and will not be described in detail here), and the seismic trace attribute parameters of each target seismic trace can be determined in the seismic profile; then, based on the seismic trace attribute parameters between adjacent target seismic traces, the apparent dip of the formation along the drilling trajectory is calculated; based on the calculated multiple apparent dips of the formation, a seismic geological guidance profile is obtained.

其中，地震道属性参数为振幅波峰、振幅波谷和过零点中的任一种。The seismic trace attribute parameter is any one of an amplitude peak, an amplitude trough, and a zero-crossing point.

进一步地，所述基于相邻的目标地震道之间的地震道属性参数，计算得到沿钻井轨迹的地层视倾角，包括：Further, the calculation of the apparent dip angle of the formation along the drilling trajectory based on the seismic trace attribute parameters between adjacent target seismic traces includes:

采用以下计算公式计算得到地层视倾角：
The formation apparent dip angle is calculated using the following formula:

其中，A为地层视倾角；H为相邻的目标地震道的振幅波峰或振幅波谷或过零点之间的高差；L为相邻的目标地震道之间的距离。Wherein, A is the apparent dip of the formation; H is the height difference between the amplitude peaks or amplitude troughs or zero-crossing points of adjacent target seismic traces; and L is the distance between adjacent target seismic traces.

具体地，在获取地震道属性参数后，基于相邻的目标地震道之间的地震道属性参数，便能够计算得到沿钻井轨迹的地层视倾角，从而得到地震地质导向剖面。Specifically, after obtaining the seismic trace attribute parameters, the apparent dip angle of the formation along the drilling trajectory can be calculated based on the seismic trace attribute parameters between adjacent target seismic traces, thereby obtaining the seismic geological steering profile.

其中，当地震道属性参数为振幅波峰时，H为相邻的目标地震道的振幅波峰之间的高差；当地震道属性参数为振幅波谷时，H为相邻的目标地震道的振幅波谷的高差；当地震道属性参数为过零点时，H为相邻的目标地震道的过零点之间的高差。Among them, when the seismic trace attribute parameter is the amplitude peak, H is the height difference between the amplitude peaks of adjacent target seismic traces; when the seismic trace attribute parameter is the amplitude trough, H is the height difference between the amplitude troughs of adjacent target seismic traces; when the seismic trace attribute parameter is the zero crossing point, H is the height difference between the zero crossing points of adjacent target seismic traces.

如图10所示，本实施方式还提供一种地震地质导向剖面的建立装置，包括：As shown in FIG10 , this embodiment further provides a device for establishing a seismic geological steering profile, comprising:

获取模块10，用于按钻井轨迹依次获取水平井垂直段和造斜段的平面坐标点；An acquisition module 10 is used to sequentially acquire the plane coordinate points of the vertical section and the deflection section of the horizontal well according to the drilling trajectory;

调整模块20，用于基于预设地震网格间距，对所述平面坐标点进行调整，得到调整后的平面坐标点；An adjustment module 20, configured to adjust the plane coordinate points based on a preset seismic grid spacing to obtain adjusted plane coordinate points;

第一确定模块30，用于基于调整后的平面坐标点和钻井预设靶点，得到目标曲线，并确定所述目标曲线与地震网格的测线的交点；A first determination module 30 is used to obtain a target curve based on the adjusted plane coordinate points and the preset drilling target points, and determine the intersection of the target curve and the survey line of the seismic grid;

第二确定模块40，用于基于所述交点，在所述地震网格中确定目标地震道；A second determination module 40, configured to determine a target seismic trace in the seismic grid based on the intersection point;

第三确定模块50，用于基于所述目标地震道，得到地震地质导向剖面。The third determination module 50 is used to obtain a seismic geological steering profile based on the target seismic trace.

本实施方式还提供一种机器可读存储介质，该机器可读存储介质上存储有指令，该指令用于使得机器执行上述的地震地质导向剖面的建立方法。This embodiment also provides a machine-readable storage medium, on which instructions are stored, and the instructions are used to enable a machine to execute the above-mentioned method for establishing a seismic geological steering profile.

以上结合附图详细描述了本发明实施例的可选实施方式，但是，本发明实施例并不限于上述实施方式中的具体细节，在本发明实施例的技术构思范围内，可 以对本发明实施例的技术方案进行多种简单变型，这些简单变型均属于本发明实施例的保护范围。The optional implementation modes of the embodiments of the present invention are described in detail above with reference to the accompanying drawings. However, the embodiments of the present invention are not limited to the specific details of the above implementation modes. A variety of simple modifications may be made to the technical solution of the embodiment of the present invention, and all of these simple modifications belong to the protection scope of the embodiment of the present invention.

另外需要说明的是，在上述具体实施方式中所描述的各个具体技术特征，在不矛盾的情况下，可以通过任何合适的方式进行组合。为了避免不必要的重复，本发明实施例对各种可能的组合方式不再另行说明。It should also be noted that the various specific technical features described in the above specific embodiments can be combined in any suitable manner without contradiction. To avoid unnecessary repetition, the embodiments of the present invention will not further describe various possible combinations.

本领域技术人员可以理解实现上述实施例方法中的全部或部分步骤是可以通过程序来指令相关的硬件来完成，该程序存储在一个存储介质中，包括若干指令用以使得单片机、芯片或处理器(processor)执行本申请各个实施例所述方法的全部或部分步骤。而前述的存储介质包括：U盘、移动硬盘、只读存储器(ROM，Read-Only Memory)、随机存取存储器(RAM，Random Access Memory)、磁碟或者光盘等各种可以存储程序代码的介质。Those skilled in the art will appreciate that all or part of the steps in the above-mentioned embodiment method can be completed by instructing the relevant hardware through a program, and the program is stored in a storage medium, including several instructions for enabling a single-chip microcomputer, a chip or a processor to execute all or part of the steps of the method described in each embodiment of the present application. The aforementioned storage medium includes: U disk, mobile hard disk, read-only memory (ROM), random access memory (RAM), disk or optical disk, and other media that can store program codes.

此外，本发明实施例的各种不同的实施方式之间也可以进行任意组合，只要其不违背本发明实施例的思想，其同样应当视为本发明实施例所公开的内容。 In addition, various implementation modes of the embodiments of the present invention may be arbitrarily combined, and as long as they do not violate the concept of the embodiments of the present invention, they should also be regarded as the contents disclosed by the embodiments of the present invention.

Claims (11)

1. 一种地震地质导向剖面的建立方法，其特征在于，包括：A method for establishing a seismic geological steering profile, characterized by comprising:

   按钻井轨迹依次获取水平井垂直段和造斜段的平面坐标点；Obtain the plane coordinate points of the vertical section and the deflection section of the horizontal well in sequence according to the drilling trajectory;

   基于预设地震网格间距，对所述平面坐标点的位置和数量进行调整，得到调整后的平面坐标点；Based on a preset seismic grid spacing, the positions and the number of the plane coordinate points are adjusted to obtain adjusted plane coordinate points;

   基于调整后的平面坐标点和钻井预设靶点，得到目标曲线，并确定所述目标曲线与地震网格的测线的交点；Based on the adjusted plane coordinate points and the preset target points of the drilling, a target curve is obtained, and the intersection of the target curve and the survey line of the seismic grid is determined;

   基于所述交点，在所述地震网格中确定目标地震道；Based on the intersection points, determining a target seismic trace in the seismic grid;

   基于所述目标地震道，得到地震地质导向剖面。Based on the target seismic trace, a seismic geological steering profile is obtained.
2. 根据权利要求1所述的方法，其特征在于，所述基于预设地震网格间距，对所述平面坐标点的位置和数量进行调整，得到调整后的平面坐标点，包括：The method according to claim 1, characterized in that the adjusting the positions and the number of the plane coordinate points based on the preset seismic grid spacing to obtain the adjusted plane coordinate points comprises:

   获取相邻的平面坐标点之间的间距；Get the distance between adjacent plane coordinate points;

   基于相邻的平面坐标点之间的间距与所述预设地震网格间距的大小关系，对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点。Based on the relationship between the spacing between adjacent plane coordinate points and the preset seismic grid spacing, the positions and number of the plane coordinate points are adjusted to obtain adjusted plane coordinate points.
3. 根据权利要求2所述的方法，其特征在于，所述基于相邻的平面坐标点之间的间距与预设地震网格间距的大小关系，对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点，包括：The method according to claim 2 is characterized in that the position and number of the plane coordinate points are adjusted based on the size relationship between the spacing between adjacent plane coordinate points and the preset seismic grid spacing to obtain the adjusted plane coordinate points, comprising:

   若相邻的平面坐标点之间的间距大于所述预设地震网格间距，则基于第一预设规则对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点；If the spacing between adjacent plane coordinate points is greater than the preset seismic grid spacing, adjusting the positions and number of the plane coordinate points based on the first preset rule to obtain adjusted plane coordinate points;

   若相邻的平面坐标点之间的间距小于所述预设地震网格间距，则基于第二预设规则对平面坐标点的位置和数量进行调整，得到调整后的平面坐标点。If the spacing between adjacent plane coordinate points is smaller than the preset seismic grid spacing, the positions and the number of the plane coordinate points are adjusted based on the second preset rule to obtain adjusted plane coordinate points.
4. 根据权利要求3所述的方法，其特征在于，所述基于第一预设规则对平面坐标点的位置进行调整，得到调整后的平面坐标点，包括：The method according to claim 3, characterized in that the adjusting the position of the plane coordinate point based on the first preset rule to obtain the adjusted plane coordinate point comprises:

   将相邻的平面坐标点中次序较小的平面坐标点确定为初始坐标点；Determine the plane coordinate point with the smaller order among the adjacent plane coordinate points as the initial coordinate point;

   在所述初始坐标点与下一相邻平面坐标点之间确定出与所述初始坐标点间距为预设地震网格间距的目标坐标点，将该目标坐标点作为调整后的平面坐标点。A target coordinate point whose distance from the initial coordinate point is a preset seismic grid distance is determined between the initial coordinate point and the next adjacent plane coordinate point, and the target coordinate point is used as the adjusted plane coordinate point.
5. 根据权利要求3所述的方法，其特征在于，所述基于第二预设规则对平面坐标点的位置进行调整，得到调整后的平面坐标点，包括：The method according to claim 3, characterized in that the step of adjusting the position of the plane coordinate point based on the second preset rule to obtain the adjusted plane coordinate point comprises:

   将相邻的平面坐标点中次序较小的平面坐标点确定为初始坐标点； Determine the plane coordinate point with the smaller order among the adjacent plane coordinate points as the initial coordinate point;

   在所述初始坐标点与下一相邻平面坐标点之间的延长线上确定出与所述初始坐标点间距为预设地震网格间距的目标坐标点，舍弃该目标坐标点与所述初始坐标点之间的所有平面坐标点，并将该目标坐标点确定为所述调整后的平面坐标点。A target coordinate point is determined on an extension line between the initial coordinate point and the next adjacent plane coordinate point, the distance between the target coordinate point and the initial coordinate point being a preset seismic grid distance, all plane coordinate points between the target coordinate point and the initial coordinate point are discarded, and the target coordinate point is determined as the adjusted plane coordinate point.
6. 根据权利要求1所述的方法，其特征在于，所述基于所述交点，在所述地震网格中确定目标地震道，包括：The method according to claim 1, characterized in that the step of determining a target seismic trace in the seismic grid based on the intersection point comprises:

   对每一交点：For each intersection point:

   在所述地震网格中，将距离交点最近的地震道确定为所述目标地震道。In the seismic grid, the seismic trace closest to the intersection point is determined as the target seismic trace.
7. 根据权利要求1所述的方法，其特征在于，所述基于所述目标地震道，得到地震地质导向剖面，包括：The method according to claim 1, characterized in that obtaining a seismic geosteering profile based on the target seismic trace comprises:

   基于所述目标地震道，构建地震剖面图；constructing a seismic profile based on the target seismic trace;

   确定地震剖面图中每一目标地震道的地震道属性参数；Determine the seismic trace attribute parameters of each target seismic trace in the seismic profile;

   基于相邻的目标地震道之间的地震道属性参数，计算得到沿钻井轨迹的地层视倾角；Based on the seismic trace attribute parameters between adjacent target seismic traces, the apparent dip angle of the formation along the drilling trajectory is calculated;

   基于所述地层视倾角，得到地震地质导向剖面。Based on the formation apparent dip angle, a seismic geological steering profile is obtained.
8. 根据权利要求7所述的方法，其特征在于，所述地震道属性参数为振幅波峰、振幅波谷和过零点中的任一种。The method according to claim 7 is characterized in that the seismic trace attribute parameter is any one of an amplitude peak, an amplitude trough and a zero crossing point.
9. 根据权利要求8所述的方法，其特征在于，所述基于相邻的目标地震道之间的地震道属性参数，计算得到沿钻井轨迹的地层视倾角，包括：The method according to claim 8, characterized in that the step of calculating the apparent dip angle of the formation along the drilling trajectory based on the seismic trace attribute parameters between adjacent target seismic traces comprises:

   采用以下计算公式计算得到地层视倾角：
   The formation apparent dip angle is calculated using the following formula:
   

   其中，A为地层视倾角；H为相邻的目标地震道的振幅波峰或振幅波谷或过零点之间的高差；L为相邻的目标地震道之间的距离。Wherein, A is the apparent dip of the formation; H is the height difference between the amplitude peaks or amplitude troughs or zero-crossing points of adjacent target seismic traces; and L is the distance between adjacent target seismic traces.
10. 一种地震地质导向剖面的建立装置，其特征在于，包括：A device for establishing a seismic geological steering profile, characterized in that it comprises:

    获取模块，用于按钻井轨迹依次获取水平井垂直段和造斜段的平面坐标点；An acquisition module is used to sequentially acquire the plane coordinate points of the vertical section and the deflection section of the horizontal well according to the drilling trajectory;

    调整模块，用于基于预设地震网格间距，对所述平面坐标点进行调整，得到调整后的平面坐标点； An adjustment module, used for adjusting the plane coordinate points based on a preset seismic grid spacing to obtain adjusted plane coordinate points;

    第一确定模块，用于基于调整后的平面坐标点和钻井预设靶点，得到目标曲线，并确定所述目标曲线与地震网格的测线的交点；A first determination module is used to obtain a target curve based on the adjusted plane coordinate points and the preset target points of the drilling, and to determine the intersection of the target curve and the survey line of the seismic grid;

    第二确定模块，用于基于所述交点，在所述地震网格中确定目标地震道；A second determination module, configured to determine a target seismic trace in the seismic grid based on the intersection point;

    第三确定模块，用于基于所述目标地震道，得到地震地质导向剖面。The third determination module is used to obtain a seismic geological steering profile based on the target seismic trace.
11. 一种机器可读存储介质，该机器可读存储介质上存储有指令，该指令用于使得机器执行权利要求1-9中任一项所述的地震地质导向剖面的建立方法。 A machine-readable storage medium having instructions stored thereon, the instructions being used to enable a machine to execute the method for establishing a seismic geological steering profile as described in any one of claims 1-9.