SU1654266A1 - Method of separating colloidal impurities, petroleum and petroleum products from oil well sewage - Google Patents

Abstract

The invention relates to physicochemical, in particular, reagent treatment of drilling waste water (BSV) containing mineral colloidal contaminations and dissolved and emulsified oil and oil products and 1 allows to increase the deposition rate of coagulated deposition and the depth of purification. BSV coagulant and flocculant subsequent settling and separation of the formed sediment provide for simultaneous input of coagulant and flocculant into the hydraulic flow of BSV with bulk with a corrosion rate of 160 m / h. It is able to increase the deposition rate of CKoaiy of colloidal contaminants 3–8 times more than by an order of magnitude to increase the depth of the eye (completely, by means of colloidal contaminants, completely remove oil and oil products from colloidal contaminants and also simplify the process Cleaners do not require a special mixing chamber BSV with the skin of the skin and flocculant 2 tablets (L C

Description

The invention relates to physicochemical, in particular, to the reagent treatment of drilling waste water (BSV) produced during the construction of oil and gas wells containing colloidal mineral and organic pollution, represented by different and organic chemicals, and dissolved and emulsified petroleum and petroleum products (NP)

The aim of the invention is to increase the deposition rate of coagulated contaminants and the depth of purification.

For the implementation of the method involving the treatment of BSV with coagulant and flocculant, subsequent settling and separation of the formed precipitate, coagulant and flocculta are simultaneously introduced into the hydraulic flow of BSV with a volumetric rate of 8,160 m / h.

Characteristics BSV are presented in table 1

Example A hydraulic pump creates a BSV hydraulic flow containing 2248 mg / l of mineral and organic contaminants as well as 87 4 mg / l of dissolved and emulsified petroleum products at a speed of 8 m / h. 300 g per 1 m3 of BSV coagulum are simultaneously introduced into the hydraulic flow. nta of aluminum sulphate and 1500 g per 1 m3 of BSV 005% solution of flocculant polyacrylamide. After treatment, BSV is discharged into a settling tank. After the discharge, the aode is settled to separate the contaminants into the sediment. The rate X) of the deposition of coagulated colloidal contaminants and NP is 0.21 cm / s.

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When a precipitate is precipitated, purified BSV contains 12 mg / l of colloidal substances and does not contain NP.

A comparison of the effectiveness of the known and proposed methods for cleaning BSV under the conditions of changing the speed of the hydraulic flow is presented in Table. 2

From the data of Table 2 it follows that the use of the proposed method of cleaning BSV from colloidal soils and NP provides, in comparison with the known method, the following advantages:

1. The deposition rate of coagulated colloidal contaminants is increased by 3-8 times.

2. More than an order of magnitude, the cleaning depth of the BSV increases due to colloidal contaminants,

3. Petroleum and petroleum products are completely removed from the wastewater composition.

4. The cleaning process technology is simplified, since a special chamber is not required.

Claims (1)

Mix BSV with coagulant and flocculant. The invention of the method of purification of drilling wastewater from colloidal pollution, oil and petroleum products, including coagulant treatment and flocculating, the subsequent settling and separation of the formed sediment, characterized in that, in order to increase the deposition rate of coagulating contaminants and the depth of purification, coagulant and flocculating are introduced simultaneously into the hydraulic flow of wastewater with a bulk velocity of 8-160 m3 / h . 0 84 BSV, BSV, VSV, BSV, BSV, BSV, BSV, BSV, BSV. 0.0 /, 0.06 0.05 0.04 0.04 0.03 0.03 0.04 0.02 318 504 462 433 471 460 397 364 415 BSV, BSV ± BSV, 162 BSV, BSVg BSV} Table 1 table 2 0.21 O, 17 O, 14 O, 12 O, 20 0.19 O, 16 O, 14 O, 17 0.03 0.04 0.03 0.02 0.03 0.04