RU183758U1 - DEVICE FOR PROCESSING THE BOREHOLE ZONE OF THE LAYER DOWN INTO A PIPE WELL - Google Patents

Abstract

The utility model relates to the field of oil and gas production, in particular to perforating and blasting operations.

The technical result of the utility model is the creation of a device for pulsed processing of the borehole zone of the formation, lowered into the well on tubing and provides an effective impact on the formation, including in horizontal wells.

The technical result of the utility model is achieved by the fact that the device for processing the near-wellbore zone of the formation, including a housing with side holes with a detonating cord and solid-fuel charges of the first group placed in it with volume and gas evolution dynamics during combustion, providing a pressure pulse in the well with a value exceeding the rock pressure , and the second group with less dynamics and a large volume of gas evolution in comparison with the charges of the first group, providing the creation of a secondary pressure front, whose pulse exceeds the duration of the first pressure pulse, while the device descends into the well at the tubing.

To actuate the device, a non-electric blasting device is used - an explosive head, the initiating pulse from which is transmitted to the detonating cord through an explosive block and through a jumper, the thickness of which is selected so as to withstand the corresponding pressure drop and ensure guaranteed initiation of the detonating cord.

The technical and economic effect of the utility model is to ensure high quality and safety of work to intensify production in horizontal wells.

Description

The utility model relates to the oil industry, namely to the field of pulsed technologies for intensifying oil production and device designs for their implementation.

A well-known method of intensifying oil production is the processing of the borehole zone of the reservoir using pressure generators [1]. In this case, the first and most powerful impulse exceeds the hydrostatic pressure in the well by 150-300 atmospheres. Subsequent decaying alternating pulsation “swings” the reservoir, increasing its oil recovery. Generator designs are well known. They have been used since the 60s of the last century and are described in detail in reference books.

Also widely used are devices that provide the formation of an additional pressure impulse with a high rate of rock loading with the formation in the near-well and remote zone of the formation of numerous extended and branched cracks that do not close after unloading [2]. In this case, the gas generator includes the assembly of charges of the first and second groups, means of ignition of the charges (detonating cord), as well as a load-carrying cable for delivering the gas generator to the well and the mounting unit of the gas generator to the load-carrying cable. The first group of charges with a smaller volume and high dynamics of gas evolution during combustion, provides the creation of a pressure pulse in the well with a value exceeding the rock pressure at a high rate of rise of the pressure pulse. The second group of charges with less dynamics and a large volume of gas evolution (compared with the charges of the first group) provides the creation of a secondary pressure front for a time several times longer than the duration of the first pressure pulse. Such devices, providing a double impact on the reservoir, are more effective.

The generators are lowered into the well on a geophysical cable, which ensures quick delivery of the device to the specified interval of the vertical well, and also allows the use of convenient electrical initiation means (electric igniters or explosive cartridges).

In recent years, there has been a growing tendency to increase the volume of construction of horizontal wells [3, 4], in which the use of devices running on cable is very difficult or impossible, therefore, it is impossible to solve the problem of intensifying fluid inflow into a well using the above-mentioned devices.

At the same time, there is a lot of experience in the use in horizontal wells of apparatus launched on a string of tubing (for example, cumulative perforators), driven by non-electric means (for example, an explosive head launched by a ball that is placed inside the string and delivered at a predetermined interval with the flow of well fluid) [5].

In order to eliminate the aforementioned difficulties, a device is proposed for pulsed processing of the borehole zone of a formation, which is delivered at a predetermined interval on a tubing string using non-electric initiation means.

The device (Fig. 1) consists of a housing 1, in which solid propellant charges of the first group 2 and second group 3 are placed, as well as a detonating cord 4. The housing has side openings for free exit of powder gases. The housing is connected to the blasting head 5, which, in turn, is attached to the tubing string 6. Any of the existing blasting heads can be used: adiabatic, hydromechanical, etc. The sealed cavity of the blasting head is separated from the unpressurized cavity of the body by a detonation transmission device 7 having an o-ring 9. The detonation from the head is transmitted to the detonating cord through an explosive block 8 and through a jumper, the thickness of which is selected so as to withstand the corresponding pressure difference in the well and atmospheric pressure in the sealed cavity of the blasting head and ensure guaranteed initiation of the detonating cord.

The device operates as follows. It is lowered into the well on a tubing string and installed in a predetermined interval. An appropriate ball is placed inside the pipe string and the pumps are started. With the flow of pumped borehole fluid, the ball moves to the blasting head and launches the latter, as a result, the initiating pulse is transmitted to the block 8, from it, through the jumper, to the detonating cord. From the detonation products of the detonating cord, the charges of the first group 2 are ignited and burned in volume mode, which ensures the generation of a pressure pulse in the borehole with a value exceeding the rock pressure at a high pulse rise rate. The products of combustion of the charges of the first group ignite the charges of the second group 3, which are burned in a layer-by-layer mode, which provides a larger gas release volume compared to the charges of the first group at a lower slew rate and lower pulse amplitude.

Text links:

1. Gunpowder pressure generators PGD.BK and ADS. Handbook of shooting and explosive equipment / Ed. L.Ya. Friedlander. M., Nedra, 1983, 197 p.

2. RF patent No. 2242600 dated February 24, 2004.

3. Tatneft increases horizontal drilling. News agency Devon 01/29/15. http://iadevon.ru/

4. TMK: horizontal drilling will make up 30% of oil production in Russia. Information and analytical portal "Oil of Russia" 02/02/14. http://www.oilru.com/.

5. V.V. Popov, Study Guide Pasque-hole full-blasting in wells / V.V. Popov; M-in education and science of the Russian Federation, South.-Ros.gos.tehn. un-t - Novocherkassk: SRSTU, 2006 .-- 212 p.

Claims (1)

A device for processing the borehole zone of the formation, including a housing with side holes with a detonating cord and solid propellant charges of the first group with a volume and gas evolution dynamics during combustion, providing a pressure pulse in the well with a value exceeding the rock pressure, and a second group with lower dynamics and a large volume of gas evolution in comparison with the charges of the first group, providing the creation of a secondary pressure front, the pulse of which exceeds the duration of the first pulse pressure, characterized in that, in order to ensure the possibility of processing horizontal wells, the device is made with the possibility of attaching to the string of tubing through a non-electric means of blasting - blasting head (hydromechanical or adiabatic), and between the tight cavity of the blasting head and the leaky cavity of the device a detonation transmission device with a sealing ring and an explosive block separated by a jumper separated from the detonating cord is located, thickness k selected in such a way as to withstand the difference between the pressure in the well and atmospheric pressure in the sealed cavity of the blasting head and to ensure guaranteed transmission of the initiating pulse to the detonating cord.

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