Development and Performance Evaluation of a Deep Water Synthetic Based Drilling Fluid System

With the enhancement of environmental protection awareness, the requirements on drilling fluid are increasingly strict, and the use of ordinary oil-based drilling fluid has been strictly restricted. In order to solve the environmental protection and oil-gas reservoir protection problems of offshore oil drilling, a new synthetic basic drilling fluid system is developed. The basic formula is as follows: a basic fluid (80% Linear a-olefin + 20% Simulated seawater) + 2.5% nano organobentonite + 3.5% emulsifier RHJ-5# + 2.5% fluid loss agent SDJ-1 + 1.5% CaO + the right amount of oil wetting barite to adjust the density, and a multifunctional oil and gas formation protective agent YRZ has been developed. The performance was evaluated using a high-low-high-temperature rheometer, a high-temperature and high-pressure demulsification voltage tester, and a high-temperature and high-pressure dynamic fluid loss meter. The results show that the developed synthetic based drilling fluid has good rheological property, demulsification voltage ≥ 500 V, temperature resistance up to 160°C, high temperature and high pressure filtration loss < 3.5 mL. After adding 2% - 5% YRZ into the basic formula of synthetic based drilling fluid, the permeability recovery value exceeds 90% and the reservoir protection effect is excellent. The new synthetic deepwater drilling fluid is expected to have a good application prospect in offshore deepwater drilling.


Introduction
With the increasing awareness of environmental protection, the requirements [7]. With continuous in-depth research ester-based ether-based poly-α-olefin, acetal and other synthetic-based drilling fluid systems have been developed.
Later, under the premise of comprehensive consideration of cost and environmental factors, researchers developed second-generation synthetic-based drilling fluids. The main types of second-generation synthetic-based drilling fluids include linear alpha-olefins, linear alkylbenzenes, linear paraffins, and internal olefins. The second-generation synthetic-based drilling fluids have better kinematic viscosity and environmentally friendly performance than the first-generation, and cost lower. The second-generation synthetic-based drilling fluids have been widely used in deepwater drilling abroad and have achieved huge benefits [8]. However, the rheology of the second-generation synthetic-based drilling fluid is greatly affected by temperature [9]. The viscosity of the drilling fluid is too high at low temperatures, and the viscosity of the drilling fluid is too low at high temperatures, especially the dynamic shear force is too low to carry the solid phase in the drilling fluid effectively [10]. At the same time, synthetic-based drilling fluids have certain thresholds in terms of high-temperature emulsification stability, oil-water ratio, and drilling fluid density [11].
This research presented in this article relies on the oil field chemistry laboratory of Yangtze University and members of the project team. The synthetic-based drilling fluid developed has good rheology, emulsification stability and temperature resistance, which meets the requirements of deep-sea drilling.

Experimental Materials
After various investigations, the experimental materials selected in this paper are of excellent value, wide source and reasonable price. The chemicals used in this article are listed in Table 1.

Optimization of Synthetic-Based Drilling Fluid System
In order to determine the formula of the synthetic based drilling fluid, the required treatment agent was optimized, and the initial formula was determined as follows: base fluid (linear a-olefin + 20% simulated seawater) + nano-organic bentonite + emulsifier + fluid loss control agent SDJ-1 + 1.5% lime CaO + appropriate amount of modified oil to wet barite BaSO 4 .

Based Fluid:Water Ratio
The effects of the ratio of different base fluids to simulated seawater on the rheology and emulsification stability of synthetic based drilling fluids were studied.
The experimental results are shown in Table 3. As the proportion of synthetic based drilling fluid decreases, the apparent viscosity and plastic viscosity of the synthetic based drilling fluid have a certain upward trend, and the emulsification stability shows a downward trend. In order to ensure the demulsification voltage of the synthetic based drilling fluid must be ≥400 V [12], the proportion of water phase should be no more than 30%.

Preferred Emulsifier
The emulsifier RHJ-1 # -5 # are selected and added to the drilling fluid base formulation respectively. The effects on the rheology of the synthetic based drilling fluid and the emulsion breaking voltage ES are shown in Table 4. It can be seen from

Optimization of Fluid Loss Additives
Several fluid loss additives for drilling fluids were selected and added to the basic formula of synthetic-based drilling fluids. The rheology, normal temperature and high temperature and high pressure water loss were measured respectively.
The results are shown in Table 5, which can be seen from Table 5. The API and HTHP fluid loss with the addition of 2.5% fluid loss agent SDJ-1 are the smallest.

Addition of Nano Organic Bentonite
The nano organic bentonite can be quickly dispersed in the synthetic based fluid to form a space grid structure with a certain strength to improve the viscosity, cutting and emulsification stability of the drilling fluid. The influence of the amount of nano-organic bentonite on the rheology and emulsification stability of synthetic-based drilling fluid was evaluated indoors. It can be seen from Table 6 that increasing the amount of nano-organic bentonite increases the demulsification voltage, viscosity and shear force of the synthetic-based drilling fluid. It is recommended to add 2% -3% of nano-organic bentonite to the synthetic-based drilling fluid system.

The Amount of Modified Oil Wetting Barite
Using modified oil to wet the barite to increase the weight, the performance of the synthetic-based drilling fluid increased from 1.05 g/cm 3 to 1.80 g/cm 3 and after 160˚C and 16 h high temperature aging the results are shown in Table 7. It is not difficult to see that the synthetic-based drilling fluid can accommodate more modified oil-wet barite. As the content of modified oil-wet barite increases, the rheological parameters of the drilling fluid increase uniformly and the emulsion stability is relatively stable.

Temperature Resistance of Synthetic Based Drilling Fluid
The performance of the drilling fluid was evaluated in the laboratory after high-temperature aging at 100˚C -180˚C for 16 h. The results are shown in Table 8. After aging in the temperature range of 100˚C -160˚C, the basic performance of synthetic-based drilling fluid has a small change range, showing that the synthetic-based drilling fluid has good temperature resistance.

High-Low-High Temperature Rheology of Synthetic Based Drilling Fluid
The high-low temperature drilling fluid rheometer was used to study the  Table 9. It can be seen from Table 9 that when the temperature changes from high to low to high, the viscosity and shear force of the synthetic based drilling fluid also change accordingly, and its emulsification stability is relatively stable. Therefore, the synthetic-based drilling fluid developed is suitable for deepwater drilling operations. Table 9. Influence of high-, low-and high temperature of synthetic based drilling fluid on performance. T

Protective Effect of Oil and Gas Layers
In order to better protect the oil and gas layer, an oil and gas layer protective Under the initiation of redox system ammonium persulfate-sodium bisulfite, reverse phase microemulsion polymerization method is used to synthesize good blocking performance.
Finally put petroleum resin and anti-collapse plugging material into a kneader according to a certain proportion, and add a small amount of surfactant, after kneading evenly, and then drying, crushing, after a 200-mesh sieve, thereby obtaining multifunctional oil and gas layer protective agent YRZ with different particle sizes. The evaluation of the reservoir protection effect is mainly based on the drilling fluid backflow permeability recovery value, temporary plugging strength, temporary plugging depth and other aspects. The synthetic-based Open Journal of Yangtze Gas and Oil drilling fluid system for protecting oil and gas layers is: the basic formula of synthetic-based drilling fluid + 1% to 5% multifunctional oil and gas layer protective agent YRZ. After adding the multi-functional oil and gas layer protection agent YRZ, the drilling fluid forms a layer of dense mud cake on the end face of the core, which is the shielding temporary plugging layer. The laboratory research evaluates the compressive strength of the shielding temporary plugging ring by changing the displacement pressure. For cores with different permeability, the shield temporary plugging ring formed on the core end face is reversely displaced under a displacement pressure difference of 3.0 MPa, and then the displacement pressure difference is increased to 10.0 MPa, and the corresponding core permeability is measured.
As shown in Table 10, as the displacement pressure increases from 3.5 MPa to 10 MPa, the core permeability is all <0.01 × 10 −3 μm 2 , indicating that a shield layer with sufficient strength has been formed inside the core, preventing the liquid phase and solid phase from further Enter the core and play a temporary blocking role.  Temporary plugging depth is a main technical index for evaluating the protection effect of shielded temporary plugging oil and gas layers. The requirement of shielded temporary plugging technology is that the plugging is shallow, pluggable, and is a temporary blockage. Select a few artificial cores in Table 11, use JHST-2 permeability gradient tester to do temporary plugging experiment first, then intercept a certain length of core along the temporary plugging end, then measure the permeability of the remaining core section and compare the core of the remaining core section. The permeability is the same as the original permeability of the entire core. If the two are close, the core length of the intercepted part can be regarded as the temporary plugging depth of the temporary plugging layer to a certain extent. The plugging depth is about 1 cm, which indicates that after the oil and gas layer protection agent YRZ is added to the synthetic-based drilling fluid system, the temporary blocking effect of the shield is good, and the dense shield layer is quickly formed only in the shallow layer of the core.
The change of core permeability after adding 2% -5% YRZ to the synthetic Open Journal of Yangtze Gas and Oil based drilling fluid was evaluated by JHDS-2 high temperature and high pressure water loss meter. The experimental results are shown in Table 12. The drilling fluid with multifunctional oil and gas layer protection agent YRZ was added. After the dynamic damage test, the shielding ring quickly formed at the contact end of the core and the drilling fluid prevented the liquid and solid phases from further intruding into the pore throat. The average permeability recovery value of the core measured after kerosene flowback reached more than 90%. Considering the cost and other factors, it is recommended to add 3% multi-functional oil and gas layer protection agent YRZ to the basic formulation of synthetic-based drilling fluid, which can meet the requirements of on-site oil and gas layer protection.
2) The synthetic-based drilling fluid developed has good rheology; good emulsification stability, demulsification voltage above 500 V; good temperature resistance, temperature resistance up to 160˚C.
3) A multi-functional oil and gas layer protection agent YRZ has been developed. After adding 2% -5% YRZ to the basic formula of synthetic-based drilling fluid, its permeability recovery value exceeds 90%, the oil and gas layer protection effect is excellent, and it has certain application prospects.

Fund Project
National Science and Technology Major Project.