Results of research of supercritical fluid CO2-regeneration process of Nickel-Molybdenum Catalysts DN-3531 and Criterion 514 are given. Regeneration was carried out with the use of pure supercritical carbon dioxide and mixture of supercritical carbon dioxide and various polar cosolvents. Regeneration process is carried out along isotherms, in the temperature range of 323 - 383 K, at pressures of P = 20 MPa and 30 MPa. Results of surface assessment of the catalyst samples regenerated show high effectiveness of suggested method.
During the last several years, many countries have imposed a reduction of sulfur level to 10 ppm in fuels, to minimize harmful products from the combustion of fuel. In the European Union, the standard “Euro V”, which specifies a maximum of 10 ppm sulfur in diesel fuels for most road vehicles, has been applied since 2009. In Russia, the formal technical requirements for fuels were introduced by Government Decree No. 118, “Technical Regulation on requirements for automotive and aviation gasoline, diesel and marine fuel, jet fuel and heating oil.” Three automotive standards cover fuel quality: Type I (Euro 3), Type II (Euro 4) and Type III (Euro 5) with a sulfur content of 350 ppm, 50 ppm and 10 ppm, respectively. Delays in implementing national fuel quality standards vary across the country, according to the refineries, which must complete the necessary upgrades [
Sulfur is the most prevalent element in the oil after carbon and hydrogen. The average sulfur content varies from 0.03 wt% to 7.89 wt% in crude oil. The sulfur content of crude oil belongs to the following groups: free elemental sulfur; mercaptans and tiols (R-SH); hydrogen sulfide; sulfides; disulfides (R-S-S-R'); polysulfides (R-Sn-R'); thiophenes, and derivatives thereof, such as benzothiophene and dibenzothiophene.
In a typical catalytic hydro-treating unit, the feedstock is deaerated and mixed with hydrogen, preheated in heater, and then charged under pressure, through a fixed-bed catalytic reactor. In the reactor, sulfur, nitrogen and oxygen compounds in the feedstock are converted into hydrogen sulfide, ammonia and water, in the presence of catalyst. The main process variables characterizing the hydro-treating process are temperature, the total pressure of the reactor, the circulation rate of the hydrogen-bearing gas, the feed space velocity, and the catalyst activity [
The selection of optimum hydro-treating temperature depends on the quality of the feedstock, the process leading conditions, the loss of catalyst activity over time, and is located within 613 - 673 K, for the compounds with boiling points within 503 - 633 K, and 573 - 643 K, the compounds with boiling points within 413 - 503 K.
The hydro-desulfurization process is a catalytic process, which removes the organic sulfur from petroleum streams [
Ethanethiol: C2H5SH + H2 → C2H6 + H2S
Mercaptans: RSH + H2 ® RH + H2S
Sulfides: R2S + 2H2 ® 2RH + H2S
Disulfides: R2S2 + 3H2 ® 2RH + 2H2S
Thiophenes: RC4H3S + 4H2 ® RC4H9 + H2S
The desulfurization reactions are exothermic and the heat of reaction ranges approximately from 2300 to 2400 kJ/m3 of hydrogen [
The refining process that removes the sulfur also reduces the content of aromatic compounds and density of the fuel, resulting in a slight decrease in the energy content of about 1%. This reduction in energy content may slightly reduce peak power and fuel economy. However, the reduction of aromatic content of diesel fuels is also relevant, because the aromatic hydrocarbons have low ethane number, contributing to the increase of vehicle emission (primarily the hydrocarbon and particulate matter).
The ease of desulfurization depends on the type of compounds. Sulfur in acyclic aliphatic sulfides (thioethers) and cyclic sulfides (thiols) are the easiest to remove [
The choice of catalysts for this process depends on the feedstock to be treated and the product required. Catalyst activity is determined by the target reaction components conversion rate. The higher activity of the catalyst, the higher space velocity the process may be carried out with to reach a great desulfurization depth.
Cobalt and molybdenum dispersed in a thin layer within the pore system of the alumina support are today generally used for the removal of sulfur, as they have proven to be very selective, easy to regenerate, and more tolerant of poisoning agents.
Since nitrogen is usually more difficult to remove from the feed stocks as sulfur, for removal of nitrogen, catalysts composed of nickel-molybdenum on alumina supports are more efficient than cobalt-molybdenum, because they have a higher hydrogenation activity, resulting in the same operating conditions, in a larger saturation of aromatic rings [
In this study, we test the use of a nickel-molybdenum catalyst supported on the alumina substrate [
The catalyst activity decreases over time due to the increase in the deposition of coke on the catalyst surface. The decrease of the partial pressure of hydrogen, in the circulating gas, tightens the process conditions and facilitates the catalyst carbonization [
This is followed by reduction of some of the compounds formed during the oxidation step, in a dilute hydrogen stream. During the oxidation, some of the sulfur on the catalyst is converted into sulfates and some metal sulfates are formed as the sulfidized catalyst is converted into the oxide form. These metal sulfates may be reduced by exposure to hydrogen at high pressure, in metal sulfides with liberation of sulfur dioxide. These reactions are highly exothermic, which may result in loss of catalyst activity or structural damage to the catalyst and the reactor.
The catalyst gradually “ages” due to recrystallization and surface structure changes, as well as due to adsorption of organometallic and other substances on the catalyst surface which block the active sites. In this case, the catalyst loses its activity and must be replaced with a new one [
An alternative to the process described above may be the regeneration of the catalyst by the supercritical fluid, which is described in this study.
The temperature of regeneration during the extraction with carbon dioxide is more than 5 times lower than the
Name of catalysts | Quality of indicators | Standard values | Scope of application |
---|---|---|---|
“Criterion 514” catalyst | Aluminum oxide content, Al2O3, wt% | 89.5 | Protective layer of kerosene hydrotreating catalyst |
Molybdenum oxide content, МоО3, wt% | 8.2 | ||
NiOoxidecontent, wt% | 2.3 | ||
1.3 and 2.5 mm sized “DN 3531” catalyst | Alumino-silicate basis―Al2O3/SiO2, wt% | 55 - 75 | Gasoil hydrotreating catalyst |
Molybdenum oxide, MoO3, wt%, less than | 30 | ||
Phosphorous pentoxide, P2O5, wt%, less than | 10 | ||
Nickel oxide, Ni, wt%, less than | 6 | ||
Iron oxide, Fe2O3, wt% | 1 - 4 | ||
Calcium oxide, CaO, wt% | 0 - 1 | ||
Potassium oxide, K2O, wt% | 1 - 4 | ||
Sodium oxide, Na2O, wt% | 1 - 4 |
Method | Traditional regeneration process | SCF regeneration process |
---|---|---|
Extractant | Ozone-air mixture | СО2 + co-solvent |
Temperature | 673 - 873 K | 323 - 383 K |
Pressure | 0.8 - 1.5 MPa | 20 -30 МРа |
Process life | 30 - 50 h | 4 - 7 h |
Number of regeneration cycles | 3 - 4 | ≥6 - 8 |
temperature of the conventional approach, which is one of the major advantages in terms of energy consumption. At temperatures lower, the catalyst does not deteriorate due to its “sintering”, which can occur at higher temperatures. The process time is reduced, and the number of possible regeneration cycles increases. By the way, in the case of the regeneration process by supercritical carbon dioxide, it is not necessary to use alkaline water to neutralize the acid exhaust gas.
The samples of spent catalyst regeneration that took place in the framework of this study were provided by the refinery “Taif-NK”.
TG chart shows the reduction in the mass of the sample, along a solid line (1) starting at 100%. FGD-mass change rate (2) is represented by a dash-dot line. The two lines illustrate how quickly the reduction of the sample mass was going on: rates have increased significantly in the temperature range from 303 K to 376 K. The mass reduction rate has subsequently fallen sharply in the temperature range from 376 K to 593 K, and has risen again in the temperature range from 593 K to 673 K, and then fell again in the temperature range from 673 K to
Temperature range, K | 303 - 593 | 593 - 788 | 788 - 1088 | 1088 - 1273 | 303 - 1273 |
---|---|---|---|---|---|
Maximum effect, K | (376) | (673) | (930) | (-) | |
Change in mass, wt% | 14.79 | 5.15 | 6.27 | 6.15 | 32.37 |
(-) no explicit thermal conversion maximum.
Temperature range, K | 303 - 498 | 498 - 573 | 603 - 823 |
---|---|---|---|
Maxima of thermal effects, K | 379 (↓) | 553 (↑) | 660 (↓) |
(↓), (↑) endothermic and exothermic effects respectively.
788 K, has risen again in the temperature range from 788 K to 930 K, then dropped to nearly zero, and increased again at the end.
Thus, according to the DSC data (solid line starting at 87), the following thermal effects were observed: the evaporation of the moisture accompanied by heat absorption (endothermic effect) occurred in the temperature range from 303 K to 498 K. Two exothermic effects in the temperature range followed this from 498 K to 593 K and from 593 K to 823 K: corresponding to substances containing respectively carbon and sulfur, respectively, deposited on the catalyst, which were burned [
The catalyst samples were regenerated in the plant shown in
The catalyst of this study, is placed in a metal basket, weighed with scales and introduced into the extractor, in the path of the fluid phase (extractant). Operating parameters of the process are set and regeneration process is carried out. Mass change of the catalyst sample is evaluated by weighing. The amount of carbon dioxide used for regeneration is also determined by the weight method.
This equipment also allows to conduct studies of the dependence of the solubility of pollutants components of the catalyst, conventionally taken as a model of coke, in pure and supercritical carbon dioxide.
One method to evaluate the efficiency of the regeneration processes is to determine the surface area of the catalyst samples regenerated according to the method described in [
A known mixture of nitrogen and helium (12% N2 + 88% He) is passed from the gas cylinder through a filter-drier and is divided into two streams. One stream is sent to the relative outlet chamber of the thermal conductivity detector. The other stream is directed into a U-shaped tube, loaded with a catalyst sample therein, and then flows into the measuring chamber of the sensor. When the U-shaped tube with a catalyst is immersed in the Dewar vessel with liquid nitrogen, the nitrogen from the feed mixture is absorbed by the catalyst sample. When the absorption is complete, Dewar vessel was removed, and the nitrogen desorption begins. The absorption and desorption of nitrogen is observed on the recording potentiometer, which detects the signal from the thermal conductivity detector. The flow rate of the mixture is regulated by valves, and the pressure is measured by pressure gauge. The curves of both adsorption and desorption and the area under either one of these curves is a measure of the nitrogen adsorbed.
The process of regeneration of Dn-3531 and 514 Criterion hydrogenation catalysts has been studied experimentally
in the following manner. To ensure a high level of saturation of supercritical carbon dioxide with deactivating compounds, the mass flow of СО2 was calibrated in a preliminary study, in order to investigate the influence of the mass flow rate of supercritical CO2 on the change in mass of deactivated catalyst (
In the first series of experiments, the catalyst samples were regenerated using pure СО2. Regeneration process is carried out along isotherms, in the temperature range of 323 to 383 K, at pressures of P = 20 MPa and 30 MPa (
A greater effect can be obtained by increasing the mass of carbon dioxide used in the method, the modification of operating parameters of the method and of the physical and chemical nature of the extractant. In the latter case, we consider the change of the extracting agent and, in addition, the use of a polar additive. The extraction with supercritical fluid, in the catalyst regeneration process, generally causes no reduction in the mass fraction of the active component, because the metals are nearly insoluble in the supercritical fluid media [
It is known that the dissolving capacity of non-polar carbon dioxide compared to polar substances is limited, which hinders the result in the development of certain technologies [
Since the forces of interaction between the co-solvent molecules and solutes are specific, it often results in improving the selectivity of the extraction process.
Studies [
Addition of modifiers such as methanol, ethanol and other in a percentage ratio from 0.1 wt% to 20 wt% can be achieved before feeding the extractant into the extractor or directly in the extractor [
The comparison of the efficiency of the catalyst regeneration with pure supercritical carbon dioxide, and modified acetone, is shown in
The addition of polar co-solvent to carbon dioxide increased the capacity to remove polar compounds included in the coke. However, it was necessary to determine the optimal physical and chemical nature of co-solvent, as well as the optimal concentration of polar additive in order to improve the result [
As in case with the flow of supercritical fluid solvent, different concentrations of co-solvent define different efficiencies of regeneration (
Therefore, the catalyst regeneration process using supercritical carbon dioxide modified with the following polar additives was carried out under a second set of experiments:
・ Dimethylsulphoxide (DMSO)
・ Acetone
Mass of solvent | Percentage of efficiency | ||
---|---|---|---|
СО2, g | Dimethylsulphoxide, g | ||
Experiment -1- | 1340 | 15.72 (≈1%) | 5.415 |
Experiment -2- | 1320 | 30.12 (≈2%) | 6.615 |
Experiment -3- | 1300 | 67.5 (≈5%) | 8.615 |
Experiment -4- | 1350 | 150 (≈11%) | 8.165 |
Mass of solvent | Percentage of efficiency | ||
СО2, g | Acetone, g | ||
Experiment -1- | 1340 | 15.72 (≈1%) | 4.95 |
Experiment -2- | 1320 | 30.12 (≈2%) | 6.115 |
Experiment -3- | 1300 | 67.5 (≈5%) | 8.115 |
Experiment -4- | 1350 | 150 (≈11%) | 7.665 |
Mass of solvent | Percentage of efficiency | ||
СО2, g | Ethanol, g | ||
Experiment -1- | 1340 | 15.72 (≈1%) | 4.415 |
Experiment -2- | 1320 | 30.12 (≈2%) | 5.615 |
Experiment -3- | 1300 | 67.5 (≈5%) | 7.615 |
Experiment -4- | 1350 | 150 (≈11%) | 7.165 |
Mass of solvent | Percentage of efficiency | ||
СО2, g | Methanol, g | ||
Experiment -1- | 1340 | 15.72 (≈1%) | 3.915 |
Experiment -2- | 1320 | 30.12 (≈2%) | 5.115 |
Experiment -3- | 1300 | 67.5 (≈5%) | 7.115 |
Experiment -4- | 1350 | 150 (≈11%) | 6.665 |
Mass of solvent | Percentage of efficiency | ||
СО2, g | Chloroform, g | ||
Experiment -1- | 1340 | 15.72 (≈1%) | 3.415 |
Experiment -2- | 1320 | 30.12 (≈2%) | 4.615 |
Experiment -3- | 1300 | 67.5 (≈5%) | 6.615 |
Experiment -4- | 1350 | 150 (≈11%) | 6.165 |
・ Ethanol
・ Methanol
・ Chloroform
First, the mass of the catalyst increases with the concentration of co-solvent and goes to a plateau, and further decreases. The maximum efficiency of the regeneration process corresponds to a co-solvent concentration equal to 5 wt% to 6 wt%. Subsequent experiments on the regeneration of catalyst samples are conducted with this value of the concentration of co-solvent (5%). The results of these studies are shown in
As can be seen in
One of the main indicators characterizing the catalyst is its specific surface area [
・ Pure alumina calcined for 3 hours at a temperature of 773 K;
Sample | Scale | Peakheight (mm) | Peakwidth (mm) | Peak area (mm2) | Volume of gas (cm3) | Specific surface area (m2/g) |
---|---|---|---|---|---|---|
Purealumina | 1:64 | 123 | 4.2 | 337,920 | 0.105 | 182.0 |
Spentcatalyst | 1:32 | 159 | 4.8 | 201,506 | 0.101 | 108.5 |
Airregeneration | 1:64 | 100 | 3.5 | 217,475 | 0.103 | 117.1 |
Regeneration with SC-CО2 + Dimethylsulph-oxide | 1:64 | 124 | 4.2 | 317,440 | 0.105 | 170.9 |
・ A non-regenerated spent catalysts sample;
・ A catalyst sample regenerated according to conventional techniques of coke burning during 2 hours at a temperature of 823 K;
・ A catalyst sample regenerated with a mixture of SC-СО2 and dimethyl sulfoxide at T = 363.15 K and P = 25 Mpa.
The results of this study are shown in
The specific surface area (m2/g) is calculated by multiplying the scale, the peak height (mm), the peak width (mm) given in
Catalyst sample regenerated with supercritical carbon dioxide, modified with dimethyl sulfoxide, has a specific surface area close to that of the pure aluminum oxide, which is not the case of the sample regenerated in air flow at 823 K. Thus, the whole regeneration, and therefore its efficiency with the supercritical fluid approach, is significantly higher than with the conventional high temperature process.
Results of the conducted research show efficiency and attractiveness of SC-CO2-regeneration process within a problem of catalysts deactivation. Increase of specific surface area of regenerated catalyst samples shows that extraction of deactivating compounds from catalyst surface was successful, and this in turn indirectly indicates on recovery of catalyst operating properties.
Authors of the present research express the gratitude to the Russian Scientific Fund (RSF) for financing of these researches within a grant 14-19-00749.
Ameer AbedJaddoa,Timur R.Bilalov,Farid M.Gumerov,Farizan R.Gabitov,B. LeNeindre, (2015) Regeneration of Nickel-Molybdenum Catalysts DN-3531 and Criterion 514 Used in Kerosene and Gas Oil Hydrotreating by Supercritical Carbon Dioxide Extraction. International Journal of Analytical Mass Spectrometry and Chromatography,03,37-46. doi: 10.4236/ijamsc.2015.33005