RU2174242C1 - Acoustic method for determination of parameters of volumetric cavities in well face area of perforated well - Google Patents

Abstract

FIELD: petroleum industry, in the first place for estimation of the quality of slit sand blast perforation of wells conducted for increasing the discharge of wells and involvement of non-drained pools in exploitation. SUBSTANCE: a wave acoustic logging with digital display of the full wave signal is carried out in the well before and after its perforation in the full interval of perforation. The mean values of all digital readings in the display ports of full wave signals are calculated per quantization step in depth before and after perforation of wells. Logging curves of the mean amplitudes of wave signals are plotted by the calculated values. The depth, volume and location of the cavities formed at perforation are judged by comparative evaluation of the degree of amplitude reduction after perforation. EFFECT: enhanced truth of information on the depth of perforation ducts and cavities, their volume and arrangement in the well face area, simplified procedure.

Description

 The invention relates to measuring equipment and can be used, in particular, for measuring the volume of internal inaccessible and buried cavities. The invention is intended primarily for use in the oil and gas industry to determine the depth, volume and location of perforation cavities and channels formed in the borehole space, for example, after conducting slotted hydro sandblasting perforation (SHGPP) on the well.

 According to the author's certificate of the USSR N 346588, M.Kl. G 01 F 17/00, G 01 F 23/28 (claimed 02.10.1970, published 07.28.1972, BI N 23) the invention is known under the name "Acoustic method for determining the amount of substance in a closed vessel", which is taken as an analog . The analogous method allows to determine the internal volume of an object by creating sound fields and measuring the reverberation time, followed by calculation using a formula that relates the volume of the object to the reverberation time, sound absorption coefficient, and surface area.

 The disadvantage of this method of determining the internal volume is that it is necessary to know the geometric dimensions of the object (all areas and volumes), as well as the sound-absorbing properties of the internal surfaces of the object in order to calibrate it.

The closest (prototype) to the claimed technical solution according to the set of essential features from among the known acoustic methods for determining the parameters of volumetric cavities is the invention according to the author's certificate of the USSR N 792078, M. Cl ³ G 01 F 17/00 (claimed 04/27/79, published 12/30/80, BI N 48) under the name "Acoustic method for determining the internal volume of an object".

 In the prototype method for determining the internal volume of an object, sound fields are created and reverberation parameters (time) are measured. At the same time, sound fields are created using the same source sequentially placed in the studied and control objects, the sound pressure levels in the diffuse zones of the created sound fields are measured, and the volume of the studied object is calculated using the formula relating the volumes of the studied and control objects, the average reverberation time, respectively in the studied and control objects and the levels of mean squares of sound pressure in the diffuse zones of sound fields in the studied and control objects.

 However, the prototype method cannot be used to determine the parameters of volumetric cavities in the near-borehole space of a perforated well, since it is practically impossible, as it is necessary for use in the prototype method, to place a sound field source in the studied object, i.e. in the cavities and channels of the borehole circumferential space, formed after, for example, slotted sandblasting perforation of the well.

 In addition, the prototype method requires additional time and money to create a control object necessary for the implementation of the known method.

 The main objective of the claimed invention is to achieve a new technical result, namely, providing the possibility with a high degree of accuracy of determining the parameters of the volumetric cavities and their location in the near-wellbore space by obtaining reliable data on the depth of channels and perforation cavities, their volume and the level of achieved connection between the well and the formation and in its circumferential space.

 Another objective of the invention is to simplify the method.

 The stated objectives of the invention are achieved by the fact that in the known acoustic method, the determination of the parameters of volumetric cavities, including the creation of sound fields and the measurement of reverberation parameters, to determine the parameters of volumetric cavities in the near-borehole space of a perforated well, we introduced the following new significant operations, namely: in the well before and after its perforation over the entire perforation interval, conduct wave acoustic logging with digital recording of the full wave signal, then calculate The average values of all digital samples in the windows for recording full wave signals for each quantization step in depth before and after perforation of a well, logs of average amplitudes of wave signals are plotted from the calculated values, after which the depth, volume and the position of the cavity formed during perforation.

 The above new significant operations are the hallmarks of the invention in relation to the known prototype method.

 From publicly available sources of patent and scientific and technical information, we do not know acoustic methods for determining the parameters of volumetric cavities in the near-wellbore space of a perforated well, in which we introduced new significant distinctive operations that provide the proposed method with a new technical result set forth for the purposes of the claimed invention.

 So, due to the fact that we proposed before and after perforation of the well to conduct wave acoustic logging with digital recording of the full wave signal, this makes it possible to use the effect of dispersion of the total energy of the wave signal on violations of the continuity and homogeneity of the rocks, which are associated with violations of the structure of rocks (cracks, cavernosity), and with heterogeneity in lithology.

 Calculation of the average values of all digital samples in the registration windows of the full wave signals for each quantization step in depth before and after perforation of the well and the construction of the log curves of the average amplitudes of the wave signals from them allows us to reliably judge the depth, volume and location of the position by the degree of decrease in amplitudes after perforation of the well cavities and channels formed during perforation of the well.

 An example implementation of the proposed method.

 The inventive method has been repeatedly tested in field conditions at oil producing and injection wells when conducting slotted hydro sandblasting perforation on them to assess its quality and effectiveness.

 So when evaluating the quality of slotted sandblasting perforations conducted on a production well in the range of 2162–2191 m, the following operations were performed according to the claimed invention. Before conducting the SHGPP in the estimated perforation interval, acoustic logging was carried out with digital registration of the wave signal (BC) in a window of 4 ms or more. In this case, standard downhole tools (such as MAK and others) with probes no more than 2 m were used. The wave signal was processed, i.e. calculated the average values of all digital aircraft samples in the registration window (4 ms) at each recording point in depth over the entire study interval. In this case, the first curve of the average values of the amplitudes of the aircraft over the interval was obtained. After conducting SHGPP conducted repeated measurements with the calculation of the second curve of the average values of amplitudes. Comparison of these 2 curves determined the degree of amplitude drop in the perforation interval. The relative change in amplitudes made it possible to assess the depth, volume of cavities, their location, the degree of connection between the well and the formation, and, accordingly, to assess the quality of perforation.

 When cutting gaps in two planes (4 holes per section) and cavity depths of up to 40 cm, the amplitudes fell about three times. The effect of a decrease in amplitudes is associated with the scattering and reflection of longitudinal and transverse waves on the surfaces of the cavities and a decrease in the amplitudes of the hydraulic waves due to the connection of the well with the perforation cavities. The largest contribution to this effect is made by hydrowaves, since their relative share in the energy of the Sun is about 70 - 80%.

 As a result of the implementation of the above-described set of operations for monitoring the quality of SHGPPs, the developers of slotted hole puncher technology received reliable information that made it possible to significantly improve both the punchers and cutting technology, which increased the quality of the formation opening and, accordingly, the volume of oil inflows obtained during well development. The application of the technology of opening the formations by the SHGPP method allowed to increase the production rates by 5–50 times and to involve non-drained formations in the development.

Claims (1)

 An acoustic method for determining the parameters of the internal volume of an object, including creating sound fields and measuring reverb parameters, characterized in that when determining the volume of cavities, their location and their connections in the near-wellbore space of the well after perforation of the well, for example, slotted sandblasting perforation, in the well before and after its perforation over the entire perforation interval, conduct wave acoustic logging with digital recording of the full wave signal, then average the values of all digital samples in the registration windows of the full wave signals for each quantization step in depth before and after perforation of the well, the logs of the average amplitudes of the wave signals are constructed from the calculated values, after which the depth, volume and location are judged by a comparative assessment of the degree of amplitude reduction after perforation the position formed during the perforation of the cavities.