BR102020016720A2 - Autonomous method of scale removal and inhibition - Google Patents

Abstract

The present invention deals with an autonomous method of removing and inhibiting scale on offshore platforms, which uses industrial or desulfated water mattresses to remove soluble inorganic deposits in the production column, with subsequent The method of this invention has as one of the focuses depleted carbonate reservoir fields and/or with very low produced water content. The solution of this invention minimizes the frequency of closing the wells, avoiding the frequent need for remote operations with a stimulation boat. The technical advantages of the new method are reduced OPEX of operations, increased NPV of operations, simplified application of chemicals in remote treatments, reduced operational risks, and reduced chemical costs.

Description

AUTONOMOUS METHOD OF REMOVAL AND INCRUSTATION INHIBITION Field of Invention

[001] The present invention deals with an autonomous method of scale treatment, aiming at the removal of soluble inorganic deposits and with chemical additives by means of scale inhibitors, in wells with high depletion index and low productivity, which are not shown more viable with conventional stimulation boat treatment costs.

Description of the State of the Technique

[002] Inorganic fouling in oil wells is caused by the accumulation of salts of low solubility in water in places such as intelligent completion valves, internal wall of the production column, valves installed in the production column, as they are reduction points in diameter. The diameter reduction provides a change in the velocity of the fluids in the wall of the tubes; that is, in the Reynolds number, right after valves, such as DHSV, VHIF, MIQ and MGL, thus creating favorable places for the precipitation of scale.

[003] The most common mechanism for the occurrence of incrustations is the precipitation of sulfates due to the mixture of incompatible waters (injection water and connate water). However, it has been verified in some wells potential fouling for calcium carbonate (CaCO3) and, particularly, halite (NaCl).

[004] The removal of halite scale is the object of this invention. One hypothesis for the presence of halite incrustation is that it occurs in wells with low BSW, in which the precipitation of this salt would be due to the evaporation of the produced water.

[005] The occurrence of saline fouling of halite in production columns would be induced by the injection of gas lift in wells with oil production with low water content.

[006] Studies of simulation of scale occurrence indicate that the high gas-liquid ratio induced by gas lift injection can generate halite deposits, due to partial or total evaporation of the produced water.

[007] The proposed mechanism shows that the oil produced with low water content (BSW less than 1%), when passing through the interior of the production column, inside the gas lift mandrel, in front of the gas lift valve ( VGL), comes into contact with the dry gas, which is being pumped through the annular space of the well, exiting through the VGL into the production column.

[008] Like dry gas, it dehydrates the oil, removing the water contained in it. With the evaporation of water, the salts that were solubilized in the water come out of solution and precipitate on the inner wall of the column, gradually forming incrustation inside the column, above the position of the VGL.

[009] The incrustation precipitation causes a reduction in the internal diameter of the column, leading to the occurrence of head loss, and, consequently, to the reduction of the well flow.

[0010] Currently, acid pumping with stimulation boat is used to remove saline incrustations. Remote acidification is carried out in an average of two operations per year in each affected well, using a weak acid (acetic or formic), being a complex logistics, but proven effective.

[0011] From a certain point in the productive life of some wells, there is a need for more frequent treatments. However, wells with high depletion and low productivity do not prove to be more viable with the costs of treatment with a stimulation boat.

[0012] Document BR1020150138334A2 discloses a method of removing saline scale in subsea equipment inside a production well, comprising low costs and low complexity. The scale removal method of this work proposes to be able to remove 100% of scale quickly, efficiently and with low costs, when compared to probe operation.

[0013] WO2017087279A1 discloses implementations that prevent, or reduce, equipment fouling using passivation as a treatment before coming into contact with hydrocarbon-containing metallic components; that is, an environment in which fouling occurs. The work relates to methods and compositions for protecting surfaces, and more particularly, to methods and compositions for protecting metal surfaces, clay surfaces, or both, in oil production and water treatment processes. The method may also include treating the process fluid; for example, via injection or batch treatment of the composition.

[0014] Also, WO2017087279A1 presents a method of passivating heat exchangers, as in a SAGD process, or systems using compositions that can be applied to a component before its first inclusion in an online system, or after placing the system offline for maintenance.

[0015] Document BR8605736A discloses a process of removing scale from the surfaces of a fluid treatment equipment, specifically using basic and acidic solutions through the equipment. The so-called vertical tube reaction equipment, in which the scale removal process is applied, can be used for industrial and petrochemical waste. The function of the process is to use a wet treatment using water in the washes between the phases of circulation of the acidic and basic solutions used. The work mentions the removal of inorganic scale, using water in the flow path, which can be reused.

[0016] However, no document of the State of the Art discloses an autonomous method of removing and inhibiting fouling on offshore platforms such as this one of the present invention.

[0017] The method of this invention seeks to minimize the frequency of closing the treatment wells, thus avoiding the constant need for remote operations with stimulation boat.

[0018] The present invention makes use of industrial or desulfated water mattresses for the removal of soluble inorganic deposits (halite) in production columns, and chemical additives by scale inhibitors.

[0019] The technical advantages of the invention are the reduction of the OPEX of the treatment operations, increase of the NPV, simplification of the application of chemical products in remote treatments, reduction of operational risks, and reduction of costs with chemical products.

Brief Description of the Invention

[0020] The present invention deals with an autonomous method of removing and inhibiting scale in offshore platforms, which uses industrial or desulfated water mattresses to remove soluble inorganic deposits (halite) present in the production column, with subsequent improvement of the treatment by chemical additives with scale inhibitors.

[0021] This invention has as one of the objectives of application fields of depleted carbonate reservoirs and/or with very low produced water content, which are no longer viable with the treatment costs with stimulation boat.

Brief Description of Drawings

• - A Figura 1 ilustrando um esquema de ocorrência de incrustação na coluna de produção, onde estão representados: espaço anular (a), precipitado (b), VGL (c), gás seco (d), fluido produzido (e);
• - A Figura 2 ilustrando um ilustrando um esquema de uma UEP (Unidade Estacionária de Produção), onde estão representados: linha de produção (LP) (1), linha de gas lift (LGL) (2), Árvore de Natal Molhada (ANM) (3), coluna de produção (CP) (4), reservatório (5), nível do mar (a), lâmina d’agua (b), linha de lama (c);
• - A Figura 3 ilustrando o detalhe do procedimento de soaking com água, com posicionamento do colchão água dentro da coluna até o reservatório, onde estão representados linha de produção (LP) (1), linha de gas lift (LGL) (2), ANM (3), coluna de produção (CP) (4), e reservatório (5);
• - A Figura 4 ilustrando o detalhe do procedimento de bullheading com óleo diesel, onde estão representados: linha de produção (LP) (1), linha de gas lift (LGL) (2), AMN (3), coluna de produção (CP) (4), e reservatório (5);
• - A Figura 5 ilustrando o detalhe do procedimento de esvaziamento da linha de produção para a partida do poço, onde estão representados: linha de produção (LP) (1), linha de gas lift (LGL) (2), AMN (3), coluna de produção (CP) (4), e reservatório (5).

[0022] The present invention will be described in more detail below, with reference to the attached figures which, in a schematic form and not limiting the inventive scope, represent examples of its realization. In the drawings, there are:

• - Figure 1 illustrating a scheme of fouling occurrence in the production column, where the following are represented: annular space (a), precipitate (b), VGL (c), dry gas (d), produced fluid (e);
• - Figure 2 illustrating a schematic of a UEP (Stationary Production Unit), where the following are represented: production line (LP) (1), gas lift line (LGL) (2), Wet Christmas Tree (ANM) ) (3), production column (CP) (4), reservoir (5), sea level (a), water depth (b), mud line (c);
• - Figure 3 illustrating the detail of the water soaking procedure, with the positioning of the water mattress inside the column up to the reservoir, where the production line (LP) (1), gas lift line (LGL) (2), ANM (3), production column (CP) (4), and reservoir (5);
• - Figure 4 illustrating the detail of the diesel bullheading procedure, where the following are represented: production line (LP) (1), gas lift line (LGL) (2), AMN (3), production column (CP ) (4), and reservoir (5);
• - Figure 5 illustrating the detail of the procedure for emptying the production line for the start of the well, where the following are represented: production line (LP) (1), gas lift line (LGL) (2), AMN (3) , production column (CP) (4), and reservoir (5).

Detailed Description of the Invention

[0023] The mechanism of occurrence of fouling in the production column is represented in Figure 1. The oil produced with low water content (BSW less than 1%), when passing through the interior of the CP, inside the gas lift mandrel and in front of the gas lift valve (VGL), it comes into contact with the dry gas being pumped through the annular space of the well, leaving the VGL into the CP.

[0024] The injection of gas lift causes the evaporation of water present in the oil and, thus, the salts that were solubilized in the water come out of solution and precipitate on the inner wall of the column, gradually forming the incrustation inside the column, above the position of VGL. In the production system, when wells, which have fouling potential, produce for the UEP via LP (1), fouling occurs first in the CP (4) and then in the LP (1).

[0025] The halite scale removal procedure, object of this invention, can be better understood with the aid of Figure 2. In general, a volume of industrial or desulfated water, with inhibitor, is pumped by the LGL (2 ) from the UEP to the ANM (3), and from there to the CP (4), where it is positioned, followed by the well opening procedures. The well's production passes through the CP (4), the ANM (3), and finally the LP (1) to the UEP.

[0026] Injection facilities are used to pump industrial water, such as an offshore tank located UEP, a hydraulic pump for pumping water, a flowmeter type flowmeter to measure the flow of water being pumped, and a pressure gauge to measure the pressure inside the tank, lines, and pump.

[0027] The first step of the procedure of this invention corresponds to the injection of a volume of industrial or desulfated water, and of inhibitor added to this water, into the CP (4), reaching the reservoir (5), performing a soaking for a period of about 4 hours, as shown in Figure 3. The inhibitor concentration is defined by laboratory tests and is in the range of 5 to 10%. To facilitate the start-up sequence of the well, the water is displaced using diesel oil to avoid the formation of hydrate inside the LP (1). The volume of water injected corresponds to about 1.5 times the volume of the CP (4), followed by a diesel mattress for displacement and injection into the reservoir (5). Diesel injection is carried out by LGL (2), going to ANM (3), LP (1), and then pushing the water volume to CP (4), reaching the reservoir (5). The volume of diesel oil corresponding to 1.5 times the volume of the production column (4).

[0028] The second step of the procedure corresponds to bullheading, where diesel oil is pumped to displace the water that was in the CP (4) into the reservoir (5), with the LP (1) being filled with diesel oil to facilitate the start from the well, as can be seen in Figure 4. The diesel injection is done by the LGL (2), going to ANM (3), LP (4), and from there pushing the water cushion into the reservoir (5).

[0029] The third step of the procedure comprises the emptying of the LP (1) for the distribution of the well, where the LP (1) to ANM (3) is filled with inert gas injected by the LGL (2), as can be seen in Figure 5. In this way, the well is prepared for distribution through the opening of the LP (1).

[0030] With the opening of the well for production and, after stabilizing the flow of the well, temperature and pressure measurements are carried out to evaluate the efficiency of scale removal.

Examples:

[0031] For this work, the following tests were performed, which represent examples of embodiment of the present invention.

Example 1: Removal of saline scale with industrial water

[0032] First, a remote acidification was carried out in well 1 by the UEP, using a stimulation boat, in order to remove scale. However, after about a month, a loss of production was identified in the well. In view of this scenario, the method of soaking with industrial water, object of this invention, was carried out to test the hypothesis of the solubility of the scale in water.

[0033] After treatment, there was a significant increase in pressure in the TPT-P, characterizing the increase in well flow (production flow practically doubled), also indicated by the increase in temperature.

[0034] The same procedure was performed in well 2. After the treatment, there was an increase in the pressure in the TPT-P, in the temperature and flow of the well.

Example 2: Comparison of losses per operation

[0035] Table 1 presents a comparison of losses per operation performed in well 1. It was found that the production losses that occurred with the water soaking procedure were much smaller when compared to the acidification procedure.

Example 3: Comparison of costs per operation

[0036] Table 2 presents a comparison of costs per operation in well 1. There was a large total reduction in costs resulting from the water soaking procedure when compared to the acidification procedure, resulting in savings in operational and logistical costs.

[0037] The results showed the establishment of a consolidated method, with instant production gain, reduction of the loss period from 30 to 2 days, savings in resources, and rapid recovery of efficiency.

[0038] Furthermore, the present invention aims to increase the longevity of the treatment with only two soaking periods with water change.

[0039] The invention can promote increased safety, due to the reduction of operations using the stimulation boat. It can also allow increased reliability for UEPs with subsea injection deficiency or failure.

[0040] Still, the present invention can be extended to wells of other types of reservoirs that present characteristics such as: production drop with indication of head loss in the column, very low BSW, high salinity, and production by gas lift.

[0041] It should be noted that, although the present invention has been described in relation to the attached drawings, it may undergo modifications and adaptations by technicians versed in the subject, depending on the specific situation, but provided that it is within the inventive scope defined herein.

Claims (8)

AUTONOMOUS METHOD OF REMOVAL AND INHIBITION OF INCRUSTATION, characterized by comprising the following steps:

• The. Align industrial or desulfated water stream to an offshore tank;
• B. Add scale inhibitor to tank containing water;
• ç. Inject through the gas lift line (2) a volume of industrial or desulfated water containing inhibitor,
• d. Perform a soaking procedure, positioning the volume of industrial or desulfated water containing inhibitor, through displacement with diesel oil, into the production column (4), reaching the reservoir (5);
• and. Perform bullheading procedure with diesel oil;
• f. Displace the water that was in the production column (4) into the reservoir (5);
• g. Fill the production line (1) with diesel oil to facilitate the start-up of the well;
• H. Empty the production line (1) for the start of the well, filling it up to the ANM (3) with inert gas injected by the gas lift line (2);
• i. Prepare the well for start-up by opening the production line (1);
• j. Open the well for production and, after stabilizing the well flow, perform temperature and pressure measurements to assess the efficiency of scale removal.

AUTONOMOUS METHOD OF REMOVAL AND INHIBITION OF INCRUSTATION, according to claim 1, characterized by the fact that the volume of industrial or desulfated water corresponds to about 1.5 times the volume of the production column (4); AUTONOMOUS METHOD OF REMOVAL AND INHIBITION OF FOULING, according to claim 1, characterized by the fact that the volume of diesel oil corresponds to 1.5 times the volume of the production column (4). AUTONOMOUS METHOD OF REMOVAL AND INHIBITION OF FOULING, according to claim 1, characterized in that the concentration of inhibitor is defined by laboratory tests and is in the range of 5 to 10%. AUTONOMOUS METHOD OF INCRUSTATION REMOVAL AND INHIBITION, according to claim 1, characterized by the fact that the soaking procedure with water is carried out for about 4 hours. AUTONOMOUS METHOD OF REMOVAL AND INHIBITION OF FOULING, according to claim 1, characterized by the fact that it improves the treatment through chemical additives with a fouling inhibitor. AUTONOMOUS METHOD OF REMOVAL AND INHIBITION OF INCRUSTATION, according to claim 1, characterized by the fact that it can be applied in wells of depleted carbonate reservoirs and/or with very low produced water content; AUTONOMOUS METHOD OF INCRUSTATION REMOVAL AND INHIBITION, according to claim 1, characterized by the fact that it can be extended to wells of other reservoirs, which have characteristics such as a drop in production with an indication of head loss in the column, very low BSW, high salinity, and gas lift production.

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