RU2072535C1 - Method of naval seismic exploration - Google Patents

Abstract

FIELD: naval seismic exploration for obtaining seismic images in presenting details of complex geological objects at stage of oil and gas prospecting; study of near-bottom sections. SUBSTANCE: receivers are used for excitation and recording of reflected waves along profile. Source and receiver are moved over profile by straight and opposite courses accompanied by change of distance between source and receiver. Source is moved by means of additional vessel at fixed distance between this vessel and main vessel; additional vessel is running at the same speed. Receiver moved by main vessel is placed along profile at definite angle of inclination relative to vertical; special device (condep) secured at end of receiver is kept at definite depth in course of motion. proposed method includes accumulation of data at various depths and processing of these data. Double summation is effected by common fixed depth point. EFFECT: enhanced efficiency. 1 dwg

Description

 The invention relates to the field of marine seismic exploration and can be used to obtain seismic images when detailing complex geological objects at the stage of exploration and development of oil and gas fields, as well as studying the structure of the bottom of the section for engineering purposes.

A known method of marine seismic exploration, which provides for the development of linear profiles MOGT using inclined receiving devices located in the water column and towed by a vessel [1]
There is also known a method of marine seismic exploration, including the excitation of elastic oscillations by a source and registration of reflected waves with a multi-channel receiving device installed with an angle of inclination along the profile in the water column and towed by a vessel [2]
The methods have the following disadvantages.

 During work, the receiving device (PU) captures information from the reflecting area of a certain length, the value of which depends on the depth of immersion of the PU, removal of the "explosion-device", the depth of the reflecting boundary. When processing the information received, the summation of the seismogram traces of the common point of the explosion occurs, which means the summation of signals coming from different sections of the reflecting boundary, smoothing, of course, all the features of the recorded wave field, this reduces the accuracy of determining the morphology of the reflecting boundaries and is completely unacceptable in engineering seismic surveys , where the requirements for the accuracy of determining the features of the bottom topography and bottom formations are very high.

 The purpose of the invention is to provide increased detail and informational content of seismic exploration at the stage of exploration and development of oil and gas fields, as well as studying the structure of the bottom topography and the bottom of the section for engineering purposes.

Данное выражение выводится из рассмотрения прямоугольного треугольника, образованного катетами Н и L/2 и гипотенузой, равной длине пробега луча от точки отражения на границе до первого канала приемного устройства.This goal is achieved by the fact that in the method of marine seismic exploration, which includes the excitation of elastic vibrations and the registration of reflected waves along the profile with a multi-channel receiving device, as well as different depth accumulation of information at a fixed reflection point, the multi-channel receiving device is moved by the main vessel with a certain inclination angle of the receiving device relative to vertical, and the movement of the source is carried out by an auxiliary vessel at the same speed as the main e ship at a given distance. The relationship between the inclination angle of the receiving device ψ ,, the distance between the vessels L and the depth of the studied object N is carried out by the expression:

This expression is derived from the consideration of a right-angled triangle formed by the legs N and L / 2 and the hypotenuse equal to the path length of the beam from the reflection point at the boundary to the first channel of the receiving device.

 The initial value of L is selected as minimal as possible, which ensures the formation of reflection and its fixation by the receiving device with the corresponding length of the receiving device and depth to the object.

A fixed inclination angle of the receiving device is achieved through the use of a special condep device, which is mounted on the end of the receiving device and, using horizontal rudders, occupies a certain depth h set from the main vessel, which provides the necessary inclination angle of the receiving device. The value of h is determined from the expression:
h = l cosψ
where l is the length of the receiver.

 This expression is derived from the consideration of a right-angled triangle formed by a leg h and a hypotenuse corresponding to the length of the receiving device with a given angle between them.

 The condep device is used in standard marine seismic surveys to maintain a stable position of horizontal receivers at a certain depth, for which several condeps are attached along the entire length of the receiver.

 Carrying out seismic exploration work while maintaining receivers with a fixed angle of inclination and carrying out work with a distance between vessels that ensures that all channels of the receiver receive information from one reflection point is the main difference between the proposed method and the prototype.

 When towing receiving devices, as described in the prototype, information is recorded from a reflecting platform of certain sizes, which depend on the depth of the object, the distance between the receiving device and the source, and the angle of inclination of the receiving device (minimum dimensions when the receiver is in the vertical position). The joint processing of this information, i.e., the summation of all channels of the receiving device, leads to smoothing of seismic fields and, as a result, distortion of the relief of the boundaries in the case of a large angle of inclination, less clear separation of faults and other features of the wave field.

 The recording of information from one reflection point allows, in the future, when summing all the channels of the receiving device with a certain shift equal to the time delay of the arrival of the wave from the same reflection point to different channels of the receiving device, to obtain a sharp signal amplification and significant interference suppression as due to statistical , and due to the lack of smoothing effects.

 Carrying out works by the direct and reverse courses of the ships with a successive change in the distance between them when changing the course allows for the second accumulation according to OGT, using the results of the first accumulation. Thus, double summation over OGT is realized, analogues of which are not yet in world practice.

 Comparison of the claimed technical solution with the prototype made it possible to establish compliance with its criterion of "novelty." When studying other well-known technical solutions in this field, technical features that distinguish the invention from the prototype were not identified and therefore they provide the proposed method with the criterion of "significant differences".

 The essence of the method is illustrated in the drawing, which shows a scheme for working out the profile of the direct and reverse course of movement of the ships. The drawing shows: 1 source; 2 receiving device; 3 main ship; 4 auxiliary ship; 5 condep; 6 reflective border; 7 surface of the sea.

 The method is implemented as follows.

 Before starting work, the following preparatory work is performed. The object of study is selected and, based on previous work, the depth from the sea surface to the object is determined along the entire length of the profile. The initial distance between the source and receiver at the point of attachment to the buoy is set. Given this distance and the depth varying along the profile to the object, the angles j are calculated and a program is created for the condep control unit. The same calculation is performed for the reverse course with a new value of L. Depending on the multiplicity of the second accumulation according to the CDP (the multiplicity of the first accumulation is determined by the number of channels of the receiving device) and the length of the hodograph of the CDP, the number of forward and reverse passages is determined and the angles j are calculated for each stroke. An explosive interval is selected. Actually, field work begins at a certain distance from the zero profile picket, sufficient to equalize the speed of ships with a given initial distance and fix the receiving device with an inclination angle calculated for a zero profile picket. At the moment of passing the last, a command is given to begin work. During the movement of the ships along the profile with a given explosive interval from the board of the main vessel, the conde is controlled and its depth is controlled, which should correspond to the angles j calculated previously.

 After practicing the direct course, the vessel unfolds and the profile is worked out in the same way as in the forward direction, while the distance between the vessels and, accordingly, the inclination angle of the receiving device are changed. Based on the designed multiplicity and length of the hodograph, a certain number of direct and reverse courses of ships is performed.

 The processing of the material obtained by this system is carried out in two stages. At the first stage, the axes of the in-phase of the rising waves are rectified and the traces are summed. In contrast to the prototype, the proposed system has two distinctive properties. Firstly, the hodograph of the rising wave has a constant slope in all seismograms, regardless of the distance between the vessels and the angle of inclination of the receiving device. The slope of the hodograph depends only on the distance between the channels and the speed of propagation of seismic waves in the water. Due to the fact that these quantities are known, there is no need, as in the prototype, to determine the laws of straightening of the hodographs of the rising waves, but it is possible to theoretically calculate the corrections introduced into the tracks in advance, and not deal with their determination. This saves a very expensive machine time and labor costs of geophysicists. It should be noted that the hodograph of the incident wave changes its slope in the seismograms depending on the distance between the vessels and the angle of inclination of the receiving device, and by this sign the incident wave is easily diagnosed.

 The second difference is that the information recorded by all the channels of the receiving device from one point of the explosion is information that came from one point of reflection. In this sense, the obtained seismogram can be called the OPV-OGT seismogram; moreover, the concept of directed properties of the system is not included in the abbreviation of the OGT, but means only the statistical effect.

 When summing the paths within the OPV-OGT seismogram, a sharp amplification of the useful signal occurs, which gives information about the structure of a particularly local part of the object, and significant suppression of satellite waves and random interference.

 At the second processing stage, the CDP seismograms are formed from the results of the first stage in the standard sense of the term and the procedures used in processing the CDP data are applied to them.

 As a result of two-stage processing, double accumulation by OGT is implemented, which has no analogues in world practice so far, which leads to obtaining time sections of high detail and resolution, which increases the accuracy of further stratigraphic analysis and prediction of the geological section. Based on the totality of profiles, interpretation and structural constructions are performed.

Таким образом, угол наклона приемного устройства должен быть в нулевом пикете профиля 14^o, изменится до 18^o на своде структуры и далее уменьшится до 12^o. Для этих случаев рассчитаем глубину погружения кондепа. Длина приемного устройства составляет 192 м (48 каналов через 4 м).As an example, let us consider the work on the proposed methodology in the Caspian Sea in the area of the Azeri field. In connection with the beginning of the development of this field, more accurate information on the bottom topography and the structure of bottom formations is needed. The depths of the sea in the chosen direction of the profile vary from 200 to 150 m in the arch of the structure (which is also expressed in the topography of the bottom), and then increase to 230 m. The initial distance between the vessels is selected 100 m. The tilt angles of the receiving device varying along the profile are calculated. depending on the depth of the bottom

Thus, the inclination angle of the receiving device should be in the zero picket profile 14 ^o , will change to 18 ^o on the arch of the structure and then decrease to 12 ^o . For these cases, we calculate the depth of the conde. The length of the receiving device is 192 m (48 channels through 4 m).

h ₁ 192cos14 192 • 0.97 186 m
h ₂ 192cos18 192 • 0.9511 182 m
h ₃ 192cos12 192 • 0.978 188 m
For the return course, increase the distance between the vessels to 200 m. We will calculate the parameters.

Далее, таким же образом выполняется расчет для совокупности прямых и обратных ходов с увеличением расстояния между судами каждый раз на 100 м до величины 600 м. Таким образом, второе суммирование по ОГТ будет 6-и кратным (первое суммирование определяется канальностью приемного устройства, в нашем случае 48). Общая кратность накапливания по общей точке отражения составит 288.

Further, in the same way, a calculation is performed for a set of forward and reverse passages with an increase in the distance between vessels each time by 100 m to a value of 600 m. Thus, the second summation over the CDP will be 6 times (the first summation is determined by the channel of the receiver, in our case 48). The total accumulation rate at the common reflection point is 288.

 Using the proposed method will improve the accuracy of structural structures due to the higher resolution and noise immunity of the obtained seismic data. The economic effect of using this method is caused by an increase in the reliability of geological results, which reduces the cost of drilling false structures mapped using less accurate data, as well as saving machine time during processing.

Claims (1)

A method of marine seismic exploration, including the excitation of oscillations by a source and registration of reflected waves with a multi-channel receiving device installed with an angle of inclination Ψ, moving along the profile of the source and multi-channel receiving device using a vessel with a forward and reverse course with a successive change in the distance between the source and the receiving device when changing course , information processing, characterized in that the source is moved using an additional vessel with a fixed distance from the main and with the same speed of movement, and the angle of inclination of the multi-channel receiving device is determined for each course of the ship relative to the vertical from the formula

where L is the distance between the vessels,
N depth from the surface of the sea to the object,
at the end of the receiving device, the conde is fixed and in the process of movement it is supported at a depth, which is determined from the expression
h = l • cosΨ,
where l is the length of the receiver,
Ψ the angle between the receiver and the vertical,
when processing information, double summation at the forward and reverse courses is carried out at a fixed common deep point.