Abstract
The oil and gas business is serious business and involves millions of dollars so whatever mitigates flow assurance is taken seriously. One of such things is natural gas hydrates. Hydrates are crystalline solids formed when water under low temperatures and high pressures encapsulated natural gases (C1–C4). They form blockages and impede the flow of gas which can lead to the loss of millions of dollars and at times lead to personnel death. Mitigation of gas hydrates has always been with chemicals especially for areas like deep offshore where accessibility is difficult. The chemicals that are in use currently are generally synthetic, expensive and hazardous to lives and environment hence the need for readily available locally sourced materials that are eco-friendly. This study considers and screens a locally sourced surfactant from the plant family caricaceae’ Extract (CE) as a gas hydrate inhibitor in a locally fabricated 39.4-inch mini flow loop of ½ inch internal diameter (ID) which mimics the offshore environment. Various pressure plots (pressure versus time, initial and final pressure versus time and change in pressure versus time) show that the CE performed better than MEG with percentage volumes of gas left in the system for 0.01–0.05 wt% of the extract having values that ranged from 76.7 to 87.33, while volume left for MEG ranged between 70 and 74.67% (1–5 wt%). The CE performed better in small doses compared to those of MEG, in all weight percentages of study. Furthermore, the inhibition capacities which show the level of performance of the inhibitors was also used as a measure of inhibition for both inhibitors. The CE inhibited systems had values of 69.3, 80.7, 78.07, 79.82, and 83.3%, while that of the MEG inhibited system was 60.53, 55.26, 73.68, 72.81, and 66.67% for the various weight percentages considered. The CE should be developed as gas hydrate inhibitors due to its effectiveness and eco-friendliness.
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Introduction
With the decline in the potential of onshore oil and gas discoveries and exploration, there is the movement by oil and gas operators offshore. This has been embraced by many countries and governments. That is accepting drilling and production offshore. Historically, in the late 1940s, the first offshore production was recorded, and by the early 70 s, about 20% of the oil supply was from offshore productions. Though onshore reserves will in due course double, offshore reserves will increase by a factor of four (4) [9], due to the advancement in technology which has brought about offshore exploration and production.
The challenges encountered during offshore production are more demanding than those encountered during onshore production. The extreme water depths, pressures, and temperatures cause the flowlines and pipelines, and production risers to be under constant strain and this leads to solid hydrocarbon depositions in form of scales, asphaltenes, waxes, and hydrates. According to [16], hydrocarbon solids can be deposited anywhere and blocked the production system. This causes constriction in the internal diameter of the systems as well as obstruction of flow hence a reduction in production.
Huge financial losses, as well as safety and environmental concerns as a result of pipeline obstructions from gas hydrates due to blockages and cessation of flow, are possible [25]. Hydrates can form when carbon dioxide is used for enhanced oil recovery according to [13]. During drilling, when a kick occurs and gas enters into the formation, subsea transfer pipelines, pipelines, chokes, Blow Out Preventers (BoPs), and risers can be plugged [28]. Even though the thermodynamic conditions for formation of gas hydrate are crossed, it does not automatically mean that hydrate plugs will be formed [16]. This is to say that even if they form, as long as they do not deposit and agglomerate, they cannot cause blockages to the pipelines and other systems.
The solid deposition causes strain on the production facility such as stenosis, increased roughness of pipe causing an increase in pump pressure, interference with valve operations, operational and safety problems (due to solid build-up in process vessels and storage tanks), reduced productivity due to clogging of perforations and sand face, plugged surface flow lines and tubing, wear and tear of equipment during mechanical handling, as well as production downtime. These lead to damages to equipment and ultimately shut down. There is, therefore, a need to prevent hydrate formation.
Gas hydrates form when water encloses gases and form cavities under high pressures (> 2900 psig) and low temperatures (32°F or 0 °C). An adequate amount of water is vital for the formation of gas hydrates. This is because its molecules are arranged in regular orientations as a result of its hydrogen bond (covalent bonding between two hydrogen and one oxygen atom gives it a peculiar property and causes it to form a hexagonal pattern, with hydrogen having positive changes, while oxygen has a negative charge). These molecules that are so aligned are made stable by hydrate formers or gas molecules in the cages formed by water molecules via weak Van der Waals forces. That is to say, guest molecules and host molecules do not bond chemically [27]. When all the cages are formed by the water molecules (host), they are made of 85% water and 15% gases [26]. Very small guest molecules such as hydrogen and helium with diameters less than 3.8 Å and large molecules such as pentane, hexane, and larger paraffin hydrocarbon with a diameter larger than 7 Å do not form gas hydrates. For hydrates to form, the hydrate former must not be more soluble than sulfur (SO2) dioxide (which is highly soluble in water, extremely temperature dependent and is about 400 times more soluble at 0 °C than at 90 °C [15]) and must not interfere with hydrogen bonding [3], and the hydrate formers are supposed to be housed inside the water cages and move freely inside without interacting with the water molecules [27] which are bonded together via hydrogen bonding. Other factors such as nucleation sites (scale, dirt, welded spot, valves, elbows, tees and roughness of pipelines) and turbulence (agitations during fluid flow and regions of high velocity) favor gas hydrate formation [3]. According to [21], they are ice-like in appearance and brittle and are formed when light ends of hydrocarbons such as methane, ethane, propane, and butane come in contact with water. Other gases such as nitrogen, carbon dioxide, and hydrogen sulfide can also form gas hydrates.
There are four techniques to prevent hydrate formation:
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(1)
Removal of free and dissolved water from the system with separators, glycol dehydration, molecular sieves, or other methods
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(2)
Maintain high temperatures so that hydrates do not form
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(3)
Maintain low pressures to keep all phases fluid
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(4)
Inject an inhibitor to prevent hydrate formation.
With technological development and the state-of-the-art methods of preventing gas hydrates, there are technology for hydrate plug prevention. Three new types of hydrate inhibitors (dispersants/anti-agglomerants, kinetic inhibitors, and emulsifiers) called low-dosage hydrate inhibitors exist asides methanol (MeOH) and monoethylene glycol (MEG) (which are known as thermodynamic hydrate inhibitors). They were field tested in the 90 s. Although the concentrations of the inhibitors are low, chemical solutions are very expensive (as flow assurance remedies) for long tie-backs between wellheads and platforms. Other technologies for hydrate prevention are slurry flow and heating/insulation.
According to [11], after laboratory studies showed a subcooling of 45 °F, the commercial use of dispersants/anti-agglomerants began in the Gulf of Mexico. They are particularly effective in hydrate plug prevention for shut-ins and restarts, although it requires more extensive field testing. These chemicals work by converting water into finely dispersed hydrate particles to be transported in hydrocarbon liquid. They are quaternary ammonium salts that are long chained which have about three or four branches that can easily form gas hydrates, but the fourth branch projects from the structure and prevents the agglomeration to larger plugs. They require hydrocarbon liquids to perform that is to say there has to be a substantial amount of hydrocarbon liquid (maximum volume of water of 40% of total liquid phase) to disperse the hydrates. The more the inhibitors are used commercially, the environmental concerns abound and have to be tackled (especially water purity).
Kinetic inhibitors are polymers containing pendant groups and carbon backbone. They act by adsorbing into hydrate cages (that are partially formed), such that the polymers are aligned along the surface of the hydrate crystal. This forces the hydrate crystals to grow around the polymers causing the hydrates to be stabilized as small particles in aqueous phase. Liquid hydrocarbon does not necessarily have to be present for this to happen. They have been found out to be effective at subcooling of 20 °F in doses of 550–3000 ppm [12], but they can still fail during shut-in and restart causing gas hydrate formation.
The dispersant/anti-agglomerants and the kinetic inhibitors constitute the low-dosage hydrate inhibitors (LDHIs). A major setback with the use of LDHIs is that the unprocessed effluent has to be produced inside the hydrate’s zone of stability [24]. Other chemical types called emulsifiers help to ensure that the water in oil phases is stabilized, so that they do not break out to form hydrates. Fadnes [10] has it that natural emulsifiers are contained in some oil, such that even when hydrate formation conditions which will convert water to hydrates are favored, the water remains stabilized in the oil phase. There has been a lot of effort to identify, extract, and reinject these natural emulsifiers (stabilizing agent) into oils that do not have them, but this has not been successful. The use of artificial emulsifiers has proved effective in gas hydrate mitigation [22]. The problem with their usage is that of cost of emulsion breakage and the cost of adapting them to suit each oil application.
Slurry flow does not allow the hydrates formed in the fluid phase to stick to the wall of the pipe. It uses the concept developed by [1]. Subsea separators are used to remove majority of the water produced and subsequent exchange of heat to temperatures of the sea floor (hydrate forming area) for a perfect slurry system. Fluids coming from the reservoir do so with high temperatures and so there is the need to preserve this high temperature or to add heat to the line so as to keep the system from entering the hydrate formation zone. This is done via coating (pipelines), pipe-in-pipe (PIP) binding (which is a concern when leakages occur and needs fixing), and use of vacuum insulated pipes (or pipes with insulating gases), but it is very expensive; hence, its commercial usage is not applicable.
A study on the effect of kinetic hydrate inhibitors on methane hydrate growth in gas–liquid separation phase was carried out by [4]. They opined that the initial position of kinetic hydrate inhibitor (KHI) had significant effect on methane hydrate growth, and that under gas–liquid separation, the two KHIs PVP and PVP-A had good inhibitory effect on gas hydrate growth. The delay of methane hydrate nucleus growth had to do with the adsorption of the molecules of the inhibitors on the hydrae nucleus surface reducing their direct contact with the surrounding water and methane molecules. In a study carried out by [14], it was found that polyurethanes had excellent adhesion properties, which were environmentally friendly, non-toxic, and non-pollutant to air and produced water. They are hydrophobic and insoluble in water and as such needed modification by incorporating ionic/or non-ionic groups in their polymer structures (this was necessitated as a result of rise in solvent cost, environmental concerns, and the ease of cleaning reactor systems, so water was used as main solvent in polyurethanes application) in order for them to be dispersed in water. The study aimed at helping to understand the importance and characteristics of polyurethanes.
These methods especially the use of chemicals (dispersants, emulsifiers, methanol, and monoethylene glycol) has been in place with varying degrees of disadvantages. The need for the use of chemicals that are more advantageous to human lives and the environment is key. This necessitated research in the use of naturally occurring plant extracts (which are water soluble and need no modification) to solve the problem of gas hydrate formation [5,6,7]. This work considers the use of such extract from Caricaceae family to inhibit gas hydrate with the aim of reducing environmental foot prints caused by synthetic chemicals.
Experimental Set up
This work is a laboratory investigation of the effect of a local an commercial inhibitor on gas hydrate formation. Experiments were run using a locally designed and fabricated laboratory Mini Flow Loop (Institute of Petroleum Studies Flow loop). For details of its specification and operation including how the experiments were carried out refer to [19, 5,6,7]. For the materials and methods as well as plant description, refer to [8]
Results and discussion
Suppression performance plots
The performance of the Caricaceae extract (CE) is screened using the laboratory flow loop which typically tells the pressure and temperature variation with time as the experiment goes on. Each of the weight percentages of the Caricaceae extract (CE) was screened on the laboratory flow loop to see the effect of the various weight percentages on hydrate mitigation.
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a) Pressure versus Time plots
The pressure versus time plots for the various weight percentages of the locally sourced surfactant, caricaceae extract (CE) are shown in Fig. 1. This plot is an indication of how well the various weight percentages regulated the pressures in the systems as compared to that of the uninhibited experiment. For 0.01 wt% CE, the decrease in pressure was from 150 to 115 psi in 120 min. 0.02 wt% had values of 150–128 psi for the same time frame; 0.03 wt% had values of 150–125 psi. For 0.04 wt%, the pressure values were 150–127 psi, while 0.05 wt% values were 150–131 at the end of 120 min. The pressure was more regulated using 0.02 wt% CE. A pressure of 128 psi was observed at the end of the experiment which was an indication that the usage of gas to form gas hydrates was lesser than in other weight percentages (except for 0.05 wt%). At this weight percentage, the local inhibitor’s profound influence on hydrate growth was brought to bear. The strong attraction between hydrophobic group and the gas molecules inhibited the mass transfer of gas molecules from the gas phase to the aqueous phase decreasing the growth rate [4]. Howbeit, the various weight percentages of the local inhibitor were all able to regulate the pressure drop in the system as opposed to the uninhibited experiment with a value of 36 psi at the end of 120 min. This could be attributed to the fact that the gas was encapsulated by water to form clathrate, thereby leading to an increase in hydrate content and decrease in total potential energy which is indicative of a sustained hydrate growth [20]. This weight percentage of 0.02 is key as it helps as a guide in hydrate inhibition in terms of volume (concentration) of inhibitor to be used above which it is no longer economical.
Figure 2 shows the Temperature versus Time plot for 0.01–0.05wt CE and uninhibited experiment. For 0.01–0.05 wt%, the temperature decreased from 30 °C to 6.5 (for 0.01 and 0.02 wt%), 7.5, 7 (0.03 and 0.04 wt%), and from 32 °C to 6.5 °C (0.05 wt%) at the end of 120 min. All the weight percentages regulated the temperatures in the system better than in the uninhibited where the temperature declined steadily from 30 °C to 27 in 20 min and then 25 °C in 30 min after which it increased to 29.5 °C in 120 min. The increase in temperature resulted in the dissolution of methane gas in the cooling water which caused a reduction in induction time (inducing the agglomeration and precipitation of crystal particles as saturation was reached signaling the onset of crystallization which is seen as a spike in temperature. This was due to the enthalpy of fusion occasioned by the release of latent heat, so that heat was given out as the experiment progressed. This is in line with the findings of [2, 20, 30]
Suppression performance comparison of caricaceae extract CE, and monoethylene glycol (MEG)
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(1)
Pressure versus Time plots
Figures 3, 4, 5, 6, and 7 show the pressure versus time for 0.01–0.05/1–5 wt% CE and MEG. As a way of comparison, the pressure versus time plot indicates how well the pressures of the system are regulated. A well-regulated system has higher pressure values with time as the experiment progresses. For 0.01–0.05 wt% CE, pressure decreased from 150 psi to 115, 128, 125, 127, and 131 psi at the end of 120 min, while pressure values for 1–5 wt% MEG for same time interval were 105, 99, 120, 119, and 12 psi, respectively.
The caricaceae extract, CE inhibited system had more regulated pressures than the MEG inhibited system in all the weight percentages considered therefore performed better. The mini flow loop used has pressure increase or decrease as an indication of hydrate formation or inhibition. A rapid pressure decrease from the base pressure during the time frame of the experiment is an indication of gas hydrate formation. When this happens, the water molecules encapsulate the gas in the system which contains the hydrate formers to forms cages. During inhibition, the inhibitors align in such a way that the water forms around them instead of forming cages. Both systems had more pressure regulation unlike in the uninhibited scenario where there was a rapid pressure decrease from 150 to 36 psi. Gas mixed rapidly with water leading to fast agglomeration and growth in hydrate crystals which is considered the first phase of gas hydrate formation [18].
The caricaceae extract CE contains bioactive compounds such as saponins, tannins, alkaloids, and flavonoids (this is the predominant constituent and is exemplified by Quercetin and catechin). They have 5 hydroxyl, OH group in them, while MEG has just 2 hydroxyl group in them. The presence of more hydroxyl groups in the extract allows for direct and faster interaction with water, thereby disrupting its ability to form crystals. MEG has inter-hydrogen bonding between its molecules which affects its interaction with water. The performance of CE may be attributed to the fact that it was used in its pristine state, unlike MEG which has been synthesized. Since MEG is a viscous fluid, this may have contributed in it not performing well unlike the CE. The growth of hydrate in the system with local inhibitor, CE was significantly slower than that of the MEG inhibited system as seen from the pressure profiles at the end of the experiment.
(2) Change in pressure (∆P) versus Time plots
The change in pressure is an indication of how much pressure was used up in the system. The lesser the pressure change, the better the efficacy of the inhibitor used. Figures 8, 9, 10, 11, 12 show the change in pressure versus time for 0.01/1–0.05/5 wt% of CE and MEG. 0.01–0.05 wt% caricaceae extract CE had change in pressure values of 35, 22, 25, 23, and 19 psi, respectively, at the end of 120 min, while 1–5 wt% of 45, 51, 30, 31, and 38 psi at the end of 120 min.
The caricaceae extract CE had the least change in pressure values in all the weight percentages and performed better than all the weight percentages of MEG, even though it was used in lesser weight percentages when compared to MEG. The local inhibitor was able to prevent hydrate by adsorption to the hydrate crystal surface due to the presence of the functional group contained in them. This is also as a result of less interaction between molecules of the gas and the water due to incomplete formation of cages, as sterical blocking occurred [4], so the local inhibitor CE was able to reduce the surface tension and form a strong hydrogen bonds with water molecules. The presence of the hydroxyl groups alongside amide groups also added to its inhibitory ability. This agrees with the fact that the effect of KHIs is mainly due to the hydrogen bond between amide group and water molecules on the hydrate surface [17], [23]. *** The uninhibited experiment had a change in pressure value of 114 psi which was greater than 0.01–0.05 wt% CE’s overall change in pressure value by 95 psi and greater than 1–5 wt% MEG overall pressure value by 76 psi. This indicated that the system was almost devoid of gas at the end of 120 min due to the encapsulation of gases by water and were well aligned around the gas molecules to form cages which trapped the gas molecules for the formation of gas hydrates [27]
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(3)
Initial (Pi) and Final Pressure (Pf) plots
The quantity of gas left in the systems is indicative of the final pressure values and denotes how the inhibitors suppressed gas hydrate formation as well as their effectiveness. Figures 13, 14, 15, 16, 17 show the initial and final pressures versus time for 0.01–0.05 wt% CE and 1–5 wt% MEG. At the end of 120 min, the volume of gas left as a measure of final pressure was 76.7, 85.33, 83.33, 84.67 and 87.33% while the values for MEG were 70, 66, 80, 79.33 and 74.67%, respectively for 1–5 wt%. Again, in all the weight percentages considered, the CE had a larger percentage of pressure retained in the system which showed its efficacy when compared to MEG. 0.02 wt% CE had a better performance than 2 wt% MEG as well as other weight percentages. This can be attributed to the fact that at this weight percentage, the molecules did not just adsorb to the water/gas surface, but were more hydrophilic and more effective in suppressing the growth of hydrate crystal [20]. For the uninhibited experiment, at the end of the experiment, the percentage was 24%. This showed the rapid use up of the gas in the system to form gas hydrate. As gas molecules dissolve continuously in the liquid phase and migrates toward the hydrate crystal nucleation zone to form new cages, there will be a continuous decrease in the number of gas molecules in the gas phase, and therefore, the dissolution rate of gas in water is reflected by the volume of gas left in the gas phase at the end of the experiment which aligns with [4]
(4) Inhibition Efficiency
The inhibition efficiency (IE) versus the weight percentage of inhibitors is shown in Fig. 18 and is a measure of the rate at which the various inhibitors performed, and further ascertains the efficacy of the inhibitors. The efficiency of caricaceae extract CE at 0.02 wt% was outstanding, because it was greater than the other weight percentages by 11.4%, 2.63, 0.88% and less than 0.05 wt% by 2.63% (mitigating at 0.05 wt% is not necessary, since the difference is not so significant, and hence, 0.02 wt% is taken as the optimum). The decreases in 0.03 and 0.04 wt% could also be attributed to reduction in their ability to inhibit. The insignificant inhibition efficiency at 0.05 wt% of the caricaceae extract is in line with a study carried out on ionic liquid where concentrations greater than 1 wt% did not offer a lot of advantage [29]. The performance at 0.02 wt% could be that at this weight percentage, the inhibitor molecules were more aligned and probably had complete adsorption on the surface of hydrate crystal, reducing the hydrate cluster/nucleus contact with water and gas molecules, to prevent growth and stabilization of the cages in all except 0.05 wt% [4]. The inhibition efficiency of the local inhibitor was greater than that of MEG in all the weight percentages considered even in lower dosages as against the higher dosages for MEG whose inhibitory performance could have been affected by its viscous nature.
Conclusions
This study has shown the effectiveness of a locally sourced surfactant caricaceae extract (CE) and its efficiency over the conventional monoethylene glycol (MEG). The various pressure plots (pressure versus time, initial and final pressure versus time, and change in pressure versus time) showed that the caricaceae Extract CE performed better than MEG with percentage volumes of gas left in the system for 0.01–0.05w% of the extract having values that ranged from 76.7 to 87.33, while volume left for MEG ranged between 70 and 74.67% (1–5 wt%). The CE was used in small doses as compared to those of MEG. The CE performed better in all weight percentages considered.
The optimum weight percentage for inhibition for the caricaceae extract (CE) inhibited system is 0.02 wt%. This is because at this weight percentage, the % volume of gas left in the system at the end of the experiment was high (85.33%). The performance at this weight percentage was attributed to the fact that at this weight percentage, the inhibitor’s molecules were more aligned and probably had complete adsorption on the surface of hydrate crystal, reducing the hydrate cluster/nucleus contact with water and gas molecules, to prevent growth and stabilization of the cages in all weight percentages except 0.05 wt%. The decreases in 0.03 and 0.04 wt% could also be attributed to reduction in their ability to inhibit. Even though 0.05 wt% had a higher volume of 87.33%, this value is just 2% above that at 0.02 wt%; therefore, it will be needless and non-economical to inhibit above 0.02 wt%. The insignificant inhibition efficiency at 0.05 wt% of the caricaceae extract is in line with a study carried out on ionic liquid where concentrations greater than 1 wt% did not offer a lot of advantage. The effectiveness of the caricaceae extract CE over MEG also comes to bear here, because MEG was used in higher weight percentages compared to the CE yet the optimum weight percentage for MEG was 3 wt% with a percentage volume of gas at the end of 80% which is 5.33% less than that of caricaceae extract CE at an optimum weight percentage of 0.02 wt%. The caricaceae extract CE is locally and readily available asides being eco-friendly and have proven to be more effective than MEG in all weight percentages considered, and therefore, it should be harnessed as gas hydrate inhibitors instead of the synthetic hydrate inhibitor MEG.
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Acknowledgements
The authors are grateful to ACE-CEFOR University of Port Harcourt and the Institute of Petroleum Studies Laboratory for their support in carrying out this research.
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Elechi, V.U., Ikiensikimama, S.S., Ajienka, J.A. et al. Laboratory evaluation of caricaceae plant as a locally sourced surfactant for gas hydrate inhibition in a laboratory mini flow loop. Appl Petrochem Res 11, 295–303 (2021). https://doi.org/10.1007/s13203-021-00275-x
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DOI: https://doi.org/10.1007/s13203-021-00275-x