RU2210792C2 - Facility to deliver geophysical instruments into inclined and horizontal holes - Google Patents

Abstract

FIELD: geophysical exploration of holes, seismic profiling in steeply inclined and horizontal holes. SUBSTANCE: facility includes containers with geophysical transmitters and rollers-centralizers, geophysical communication cable and tubular members with grooves and elastic couplings. Containers are interjoined by means of elastic braces formed by sections of geophysical cable carrying system of cylindrical washers comprising springy elements and rigid casings. Casings are fixed on sections of cable. Springy elements are embedded with one end in casings. Length of springy elements is not less than radius of hole at start of its inclined section. EFFECT: widened functional capabilities of facility. 4 dwg

Description

 The invention relates to geophysical research of wells and may find application in conducting downhole seismic profiling in steeply inclined and horizontal wells.

 The well-known Simphor system for conducting geophysical surveys in horizontal intervals of directional wells, delivering geophysical instruments by pushing, which includes: a logging probe in a protective casing, a special sub with a side hole for a logging cable, a drill string plug and an immersion rod at the end of a logging cable while the gap between the drill string and the rod is selected based on the possibility of moving the rod in the drill string through the drilling fluid. Logging is performed as the drill string is lowered, from which the rod is extruded [1].

 The disadvantage of the system is its functional limitation, since the rigid joint of geophysical instruments with the rod sharply limits the frequency response of downhole seismic sensors and is not suitable for downhole seismic profiling.

 A device is known for transporting geophysical instruments into deep directional wells, including: a rod, a carriage with a slider and wedged supports mounted on a rod that can be moved along it and connected to one end of the traction cable, a drive with a drum connected to the other end of the traction cable, a spring mounted on the rod between the emphasis on it and the carriage, carriage stops, an additional spring and bushings, and the stops are installed in the head of the rod and on the carriage with the side of the spring, with the additional spring placed on a slider that is connected to the traction cable, the bushings are placed on the support levers and pivotally mounted on the slider, and the drive with a drum is equipped with a clutch connected to the carriage limiters and placed inside the rod [2 ].

 The disadvantage of this device is that it requires additional mechanisms, power systems and control, which increases the likelihood of failures and accidents during transportation. In addition, the speed of movement along the horizontal section of the well is small, which makes it impossible to transport devices to the required distances for a limited period of time.

 A device for logging in inclined and horizontal wellbores is known, including: containers with geophysical sensors, a geophysical communication cable, tubular elements, feeders for tubular elements and a geophysical cable, the containers with geophysical sensors provided with centering rollers and interconnected by rigid ties, and tubular elements contain grooves for fixing the geophysical cable in them and are equipped with flexible couplings.

 The disadvantage of the device is its functional limitation, since the rigid connection of the containers with each other changes the amplitude-frequency characteristics of geophysical sensors in the field of seismic frequencies, which makes it impossible to use the device for conducting downhole seismic profiling.

 The objective of the invention is to expand the functionality of the logging device when conducting downhole seismic profiling. The objective of the invention is solved in that in a device for delivering geophysical instruments to deviated and horizontal wells, containing containers with geophysical sensors and centering rollers, a geophysical communication cable and tubular elements with grooves and elastic couplings, the containers are interconnected by elastic ties formed by segments of the geophysical cable bearing a system of cylindrical washers consisting of elastic elements and rigid cages, while the cages are fixedly mounted on the cable segments, and the elastic elements cients one end fixedly mounted in the holder, and the length of the elastic members is not less than the radius of the well at the beginning of its inclined portion.

 The connection of containers containing geophysical sensors, including geophones, with elastic connections between themselves into a single system allows us to ensure compliance with the amplitude-frequency characteristics of geophysical sensors in the vertical and horizontal position of the containers containing them. This is due to a decrease in the resonance properties of rigid bonds due to the replacement of tubular elements by a geophysical cable having a certain elasticity in the transverse direction.

 Cylindrical washers, which are cylindrical "ruffles", fixed by clips on the geophysical cable, provide elasticity of the elastic geophysical cable against lateral bending when pushing containers with sensors inside a horizontal well. In this case, the elongated elastic elements (ruffs) are supported by their protruding ends on the walls of the well at individual points along the perimeter. This ensures that the cable is centered on the axis at any point in the inclined and horizontal sections of the well and the fluid flows around these elements with the drilling fluid.

The proposed device is illustrated by drawings, where:
figure 1 shows a diagram of a delivery device;
figure 2 is a view along aa of figure 1;
figure 3 diagram of the curvature of the cable;
figure 4 is a diagram of the bending of a single elastic element.

 A feature of the geophysical cable is its lateral flexibility, which makes it impossible to directly use it as a pusher, that is, replace it with rigid tubular elements of a known device [3]. A slight initial deviation of the cable from the direction of the straight line quickly leads to an increase in the amplitude of this deviation in the presence of a resistance force directed along the axis of the cable. However, the armored cable has elements of lateral elasticity, which manifests itself in the fact that a cable segment of a certain length maintains a horizontal position under the influence of not only its own weight, but also some additional force applied to the end of this segment.

 Therefore, to push the garland of containers into a horizontal well, interconnected by segments of a geophysical cable, it is necessary to ensure a parallel position of the cable to the axis of the well, regardless of its direction in space, while simultaneously controlling the local curvature of its trunk. Technically, this is possible if you place a number of cylindrical washers on the cable surface, consisting of elongated elastic elements, for example, of individual thin elastic steel wires, one of the ends of which rests freely on the surface of the well, and the other is pinched in cylindrical cages. These clips, in turn, are fixedly mounted on the cable with a step not exceeding the elastic length of the used cable mark “l”.

 The number of elastic elements in each cylindrical washer can be determined from the equation of moments relative to the vertical axis of one curved element under the action of forces arising from local bending of the cable section.

From ΔABC (figure 3) we find that F ₂ = F ₀ sinα, but
sinα = Δh / (Δh ² + l ^{2/4) 1/2,} so F ₂ = F ₀ d / l (1)
for d / l <1, since Δh cannot be greater than d / 2.

Here: F ₀ - push resistance, d - well diameter, Δh - cable deviation from horizontal position, l cable elastic length.

It is known that under bending deformations of structural elements there is a certain critical load at which this structural element restores its original shape after unloading [4]. This load is associated with the design and material parameters as follows:
F _cr = π ² JE / (μH) ² (2)
where J is the moment of inertia of the cross section, E is the Young's modulus of the material, H is the length of the structure, and μ is the ghost coefficient.

Using this expression, we can calculate the critical load on one elastic element, and comparing it with the force from (1), find the number of these elastic elements:
F _cr = π ³ (D ⁴ E / 256H ² ) (3)
In (2) Substituting the moment of inertia of a circular cross section _KP J = π (D ^4/64) and μ = 2. D is the diameter of the cross section of one elastic element.

где d - диаметр скважины, Н - длина упругого элемента (Н≈d/2), l - длина упругости кабеля, D - диаметр упругого элемента, Е - модуль Юнга материала упругого элемента, F₀ - сила сопротивления проталкиванию (вычисляется отдельно и зависит от свойств скважины). Вместе с тем, кабель и упругие элементы, находящиеся в деформированном состоянии (изогнуты) при контакте со стенками скважины, образуют резонансную систему, способную передавать механические колебания регистрирующим датчикам и создавать таким образом дополнительные источники помех. Оценим собственные частоты деформированного упругого элемента, для чего используем уравнение колебаний кольца радиуса R в виде:

где и - поперечное отклонение от положения дуги окружности, R - радиус кольца, χ - радиус инерции поперечного сечения кольца относительно оси, проходящей через центр тяжести сечения, θ - переменная угловая координата.From (1) and (3) we find that the number of elastic elements in the washer must be at least n

where d is the diameter of the well, N is the length of the elastic element (H≈d / 2), l is the length of the cable elasticity, D is the diameter of the elastic element, E is the Young's modulus of the material of the elastic element, F ₀ is the push resistance (calculated separately and depends from the properties of the well). At the same time, the cable and the elastic elements in a deformed state (bent) upon contact with the walls of the well form a resonant system capable of transmitting mechanical vibrations to the recording sensors and thus create additional sources of interference. We estimate the natural frequencies of the deformed elastic element, for which we use the equation of oscillation of a ring of radius R in the form:

where and is the transverse deviation from the position of the circular arc, R is the radius of the ring, χ is the radius of inertia of the cross section of the ring relative to the axis passing through the center of gravity of the section, θ is the variable angular coordinate.

где ρ, Е и R - плотность, модуль Юнга материала и начальный радиус изгиба (5).

where ρ, Е, and R are the density, Young's modulus of the material, and the initial bending radius (5).

 This equation can be used to the full extent, since the bending of the elastic element can be thought of as occurring along an arc of a certain circle of the corresponding radius. A harmonic driving force acts on the elastic element, which excites displacements in the transverse direction of the form u = A (θ) sinωt, with a frequency ω Hz.

The ends of the elastic element (one on the cable, the other on the well) are subject to rigid jamming conditions of the form u = 0, du / dθ = 0 at θ = ± θ ₀ , where θ ₀ is the angular size of the curved elastic element.

Анализ (7) показывает, что физически непротиворечивое решение реализуется при

Это дает соотношение

где k= 0,1,2... Отсюда из (7) можно найти, что частоты механических колебаний упругого элемента подчиняются уравнению:

Из этого уравнения находим, что

или

при стандартных величинах диаметра скважины (d=127 мм) и диаметра кабеля и его возможного отклонения от центра скважины.The procedure for finding a solution to equation (5) is known [5], therefore, we write the result in the form of a transcendental equation relating the parameters of the well, the perturbation amplitude, and the inertia radius of the cross section of the elastic element

Analysis (7) shows that a physically consistent solution is realized when

This gives the ratio

where k = 0,1,2 ... From this it can be found from (7) that the frequencies of mechanical vibrations of an elastic element obey the equation:

From this equation we find that

or

with standard values for the diameter of the well (d = 127 mm) and the diameter of the cable and its possible deviation from the center of the well.

From here we find the frequencies of mechanical vibrations transmitted by the flexible element, taking into account the value of ω ₀ from (6)
ω ₀ = 1.6 kHz;
ω ₁ = 1.54 kHz;
ω ₂ = 1.4 kHz;
ω ₃ = 1 kHz;
ω ₄ = 224 Hz.
The formula for calculating ω _{0 /} (6) includes the bending radius of the elastic element 6. FIG. 4 shows that from geometric considerations and assuming the approximation of small bending deformations, we can assume that the bending occurs along an arc of some circle or close to it, we find that: R ² = (d / 4) ² + (R-χ) ² or after transformations and the condition that χ / R << 1, we obtain: R≈d ² / 32χ.

 Analyzing the sequence of frequencies from (8), we will make sure that the flexible element transmits mechanical vibrations outside the seismic range, so they are not obstacles for conducting downhole seismic profiling.

 Mechanical vibrations with other frequencies are absorbed by elastic washers and do not reach the recording sensors through a communication cable 2.

 Thus, the proposed technical solution does not actually change the amplitude-frequency characteristics of geophysical sensors located in containers 3.

 According to the invention, in the well 1 containing an inclined or horizontal section, the garland of containers is assembled. To do this, from the segments of the geophysical cable 2 form a system of elastic ties between containers 3, by fixing cylindrical washers 4 on them, consisting of clips 5 and elastic elements 6.

 Moreover, each segment of the geophysical cable 2 is divided into an integer number of parts, the length of which is not greater than the elastic length of a given brand of cable. At the ends of these sections, cylindrical clips 5, which are split into two equal parts, are rigidly fixed, for example with bolted connections. These cylindrical lobes contain elastic elements 6 rigidly pinched at their ends, made, for example, in the form of thin steel wires combined into brushes 7. The brushes 7 are placed on the lobes of the clips 5 so as to form elastic elements 6 like urchins uniformly protruding in all directions " In this case, between the brushes 7 located along the circumference on the same clip 5, empty spaces are left (Fig. 4). Then they begin to assemble the garland by sequentially connecting the containers 3 with elastic ties. To the uppermost container 3 is additionally connected via the same elastic connection the pusher load 8, which serves to attach the first tubular element 9.

 After that, a garland of containers 3 with a weight pusher 8 is hung with a lifting mechanism and lowered into the wellbore 1, sequentially increasing the tubular elements 9. At the entrance to the horizontal section of the well 1, the speed of the system decreases. If the garland system continues to move under the action of the weight of the vertical part of the tubular elements 9, then lowering continues. Otherwise, the lowering is stopped, a mechanism for additional vertical pressure is attached to the tubular elements 9, and the descent procedure is continued until the specified length of the unwinding of the geophysical cable 2 is reached. After that, the cable 2 is lowered and the containers 3 are pressed against the walls of the horizontal section of the well 1.

 The proposed technical solution has ease of execution; using traditional mechanical means for conducting well research, it allows seismic measurements to be carried out not only with one, but with several containers at once, i.e. lower the garland of seismic sensors into the well. In addition, the proposed device makes it possible to conduct seismic profiling of both vertical and horizontal sections of the same well without removing tubular elements to the surface due to elastic ties between the individual containers.

Sources of information:
1. Blakley W. -B. -Ifpand Elf - Aguitain solve horizontal well logging prollem Petrollem Engineer International, 1983, y.55, 14. P. 22-24.

 2. USSR Copyright Certificate 1105625 for 1984

 3. US patent 4415805 for 1983 (prototype).

 4. The resistance of materials. - IN AND. Feodosiev, 1979, M., Nauka, Main Edition of Physics and Mathematics. S. 120-143, 430-436.

 5. The dynamic theory of sound.-G. Lamb. 1960, M., State Publishing House of Physics and Mathematics. S. 174-181.

Claims (1)

 A device for delivering geophysical instruments to inclined and horizontal wells, containing containers with geophysical sensors and rollers - centralizers, a geophysical communication cable and tubular elements with grooves and elastic couplings, characterized in that the containers are interconnected by elastic ties formed by segments of the geophysical cable carrying a system of cylindrical washers consisting of elastic elements and rigid clips, with the clips being fixedly mounted on the cable segments, and the elastic elements at one end m are rigidly mounted in these holders, and the length of the elastic elements is not less than the radius of the well at the beginning of its inclined section.

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