SU1596077A1 - Method of removing sodium chloride deposits in underground gas production equipment - Google Patents

Abstract

The invention relates to the field of the control of salt deposits in the process equipment of the oil and gas industry. The purpose of the invention is to reduce the intensity of the separation of sodium chloride deposits from the surface of gas production equipment and prevent them from blocking the elevator tubes when flushing wells. When flushing the wells from sodium chloride deposits into the water, before entering the well, a foaming agent is added in an amount of 0.1-2 wt.% And the washing is carried out with foam. Water containing surfactant is transferred to foam either at the well bottom when gas passes through it, or on the surface before being pumped into the well by mixing with gas. This method reduces the number of well overhauls by reducing the number of wells plugged by the breaks in the flushing salts. 2 hp f-ly.

Description

The invention relates to the control of salt deposits in process equipment and can be used in the development of fields and the extraction of natural gases.

The purpose of the invention is to reduce the intensity of the separation of sodium chloride deposits from the surface of gas production equipment and prevent them from plugging elevator pipes when flushing wells — by washing the wells from sodium chloride deposits into the water before entering the well, additional foaming agent is added in amount 0.1-2% by weight (optimal foaming conditions) and washing is carried out with foam. Moreover, water containing surfactant,

is transferred to the foam either at the well bottom when gas passes through it, or on the surface before being introduced into the well by mixing with gas.

The essence of the method is as follows.

When flushing the well with water, the last fractures in the salt deposits penetrate to the surface of the gas production equipment. Further, the salt dissolution process can proceed along the salt-surface interface of the gas production equipment. This will lead to a decrease in the bonding force of the deposit with the surface of the gas production equipment and the separation of the deposits under the action of its own weight. The consequence of this is the blockage of squash ve vi VI

saline and the need for capital repairs. When surfactant is added to water, the surface tension decreases. This leads to a decrease in capillary forces, resulting in a decrease in the penetration of water into the pore space and microcracks. Foam, in comparison with water, has a much higher viscosity, which reduces its speed along sludge cracks. In addition, individual cracks in the sediment will be blocked with foam cells. The combination of these factors will lead to a sharp decrease in the advancement of water through sediment fractures and the rate of its penetration through cracks to the equipment surface. All of this will contribute to a uniform surface dissolution of the sediments and will significantly reduce the likelihood of sediment detachment and prevent them from plugging gas production equipment.

Example 1. Sodium chloride deposits are removed in an underground gas field equipment using foam obtained at the surface. For this purpose, surfactants Syntanol DS-10 are dissolved in water by mechanical mixing in an amount necessary to ensure its concentration in water 2% by weight, i.e. per 100 kg of the solution take 2 kg of Sintanol DS-10, water the rest. Then, using a known method, mixing the gas (air, natural gas, etc.) and water containing the surfactant in the aerator using pump-and-compressor equipment, the foam is pumped into the well. Circulate foam in the well. For example, foam is pumped into the annulus, and removed through tubing, or pumped into the tubing, and removed through the annulus. Moreover, the degree of aeration of the foam is selected so that it can be removed from the well under the influence of the energy of the produced gas, i.e. during the flushing of the salt plug, the well should flow. This will prevent the ingress of water into the bottomhole formation zone and the deterioration of its reservoir properties. The calculation of the required degree of aeration depending on the well design and its productive characteristics is made on the basis of the known dependences of the density of two-phase foam on the well depth and degree of aeration. In order to avoid calculations, the degree of aeration is fed into the working well on the torch foam periodically. Moreover, the amount of liquid in the foam should be such that when it is removed from the well under the action of the energy of the gas-liquid flow of the well, the back pressure develops, which is equal to the pressure in

collector. For example, when the pressure in the reservoir is 1.4 MPa, the amount of water pumped into the well must be such that the height that the volume of water in the elevator takes 5 is not more than 140 m, i.e. foam back pressure was on the order of 1.4 MPa. Washing is continued until the deposits are completely removed from the surface of the gas production equipment, which is controlled by patterning

0 wells either by measuring the salinity of the discharged water.

EXAMPLE 2 Sodium chloride deposits are removed in gas well lift tubes with foam, which is obtained at the bottom of the well when gas passes through water containing surfactant.

To do this, surfactant OP-7 is dissolved in water in the amount necessary for providing its concentration of 0.1 wt.%, I.e. per 100 kg of solution take 0.1 kg of OP-7, the rest of the water. Then, with the help of pumping equipment in the annulus of the torch-powered wells, tubes are pumped in portions of the aqueous solution of surfactant. The volume of one portion of the injected water is such that the height that this volume will occupy in the elevator would provide the back pressure to the reservoir not exceed the pressure in the reservoir. Stack on the bottom of the well, this

0 when mixed with gas, it forms a foam. The multiplicity of the bottomhole foam is determined by the characteristics of the gas-liquid flow and varies from 2 to 25. The flushing is continued until the sediments are completely removed from the surface of the gas production equipment, which is controlled by well patterning or by measuring the salinity of the water carried. The proposed method reduces the number of

0 well overhauls by reducing the number of wells plugged by the breaks in the flushing salts.

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Claims (3)

1. A method for removing sodium chloride deposits in an underground gas field equipment by washing it with water injected from the surface, characterized in that. 0 what In order to reduce the intensity of the separation of sodium chloride deposits from the surface of gas production equipment and blockage of elevator pipes during flushing of wells, additional foaming surfactant is added to the water before entering the well in an amount of 0.1-2 wt.% followed by aeration. . 2. Method pop. 1, characterized in that aeration is carried out at the bottom of a well when gas passes through it. 3. The method according to claim 1, 1 and 2, and prior to injection into the well by means of the assumption that aeration is performed on the surface with gas.