Oil shale samples from Sultani oil shale mine, south of Jordan, were pyrolyzed by a partial combustion to generate shale oil. The produced water was sent for analysis. The different samples were analyzed for carbon content, and results showed that the TOC was 2010 mg per liter of retorted water. Phenol and arsenic contents were measured and found to be 64 mg and 0.18 mg per liter respectively. Phosphate and sulfate were also determined and found to be 35.7 and 5022 mg per liter. On the other hand, ammonium was also found to be 2831 mg per liter. Several elements were traced and reported in the present work, in which arsenic, chrome and nickel are the most important, and the retorted water was found to contain 0.18, 0.7 and 0.5 mg per liter.
Water is necessary for producing shale oil. The amount and quality vary with technology. Typical uses include process cooling, reclamation, and dust control. The municipal needs result from any population increase due to oil shale workers and supporting businesses.
Water is produced during the processing (retorting) of oil shale that is not indigenous or tributary to local ground water or streams. It amounts to between 4 and 14% of the shale oil produced. Therefore an average of 10% of the required indigenous water may be saved by treating this water and using it within the project [
Oil shale retorted water is produced due to pyrolysis and/or combustion of oil shale. As a result of these processes, water liberated from clay, intermolecular water, and chemical reaction waters are termed retorted waters. The oil shale retorting process is unique, as the resulting wastewater contains large amounts of oil, sulfide, cyanide, volatile phenol, ammonia, and other toxic substances; it has high content of COD and refractory material and more [
All liquid effluents from the oil shale thermal treatment plants consist of three wastewater streams [
Earlier investigators [
Thiosulfate and thiocyanate were major constituents in four retort wastewaters derived from combustion-type processing of oil shale. Thiosulfate was the predominant sulfur species with concentrations ranging from 420 to 2200 milligrams per liter. Thiocyanate concentrations ranged from 24 to 720 milligrams per liter [
In this work, the oil shale sample was taken from Sultani mine and subjected to partial combustion to retortoil shale to produce shale oil without external heating source. During this process, a large amount of water is produced due to dissociation of the different forms of water from mineral content present in the oil shale and generated in the combustion process and pyrolysis. With the available equipment, we have tried to identify the different pollutant and contaminants of the retorted water.
The oil shale from the Sultani mine is crushed and sieved to 10 - 50 mm size using ASTM standards. The retort is a 50 cm diameter and 120 cm long unit. The retort is designed to facilitate initial heating through an external source until the temperature of the oil shale is high enough to initiate auto ignition of the shale. The temperature of retort was monitored and measured through different thermocouples located at different position of the oil inside the retort. The maximum temperature achieved in the retort was 600˚C which is reported in the combustion region below the pyrolysis section of the retort. The retort is equipped with a suction system and condensing heat exchanger to withdraw generated gases and condense the hydrocarbon respectively.
Several runs were conducted on the retort with each run sample size varying between 30 kg to 50 kg of sample. The collected liquid is taken for decantation, where water is withdrawn from the bottom of the vessel. The same sample of water was distributed into different smaller samples and sent for analysis.
The experimental set up is shown in
The retort was operated mainly to generate shale oil for calculating the yield, and analyzing and characterizing the produced shale oil. The produced water was considered as a secondary byproduct, where it was taken for analysis to identify the different contaminants due to the pyrolysis and combustion processes. These pollutants are hydrocarbon and mineral sourced components.
The oil yield which is based on Fischer assay calculations was not calculated, due to excessive burning although simple calculations show that it is close to 50%.
The produced water from retorting oil shale contains dissolved, suspended solids, organic compounds, inorganic materials, and hydrogen sulfide. In general, the retorted water is found to contain several compounds such as: Phenols, sulfate, Chlorides, Nitrogen, phosphorus, Oil Products, Suspended Solids, Alcohol, ketones, aldehydes, lactones, pyrrole, Dissolved Organic Carbon, Carboxylic Acids, Formic acid, Acetic acid, Benzoic acid, Toluene, Hydroxyl Benzene, Aromatic Amines, Aniline, Amine, Pyridine, Quinoline, Amide, Nitriles, Ammonia, Carbonates, Thiocyanate, Nitrate, Copernicium, Arsenic, Zinc, Chromium,
Item | Carbon wt. %. | Hydrogen wt. % | Nitrogen wt. % | Sulfur wt. % | Calorific Value, kJ/kg |
---|---|---|---|---|---|
1 | 76.325 | 9.300 | 1.43 | 11.388 | 34,200 |
2 | 77.725 | 9.422 | 1.367 | 10.94 | 39,558 |
Lead, Iron, Bromine, Cadmium, Silver, Mercury, Scandium, Boron, Barium, Copper, Molybdenum, Fluorine, cesium, Tin, Ruthenium, Aluminum, manganese, indium, iodine, antimony, tungsten, zirconium, Cerium, vanadium, yttrium, europium, dysprosium and lutetium, hydrogen sulfide, carbon dioxide, Calcium, Magnesium, Potassium, Sodium, Fluoride, Organic carbon.
Since it is desired to investigate the presence of some of these earlier mentioned chemical compounds, the test performed in this research work for the selected component is dictated by the availability of the equipment capable of detecting and measuring these chemicals.
In the coming section, each investigated material will be discussed with respect to the equipment used, place of conducting these tests, and the results obtained.
The term TOC indicates total organic carbon presenting in retorted water. This test reports the total organics, with identification of the chemical formula and type. This investigation’s work is performed in Dar Al Dawa Company laboratories. Analytical technologies utilized to measure TOC share the objective of completely oxidizing the organic molecules in a liquid of sample water to carbon dioxide (CO2), measuring the resultant CO2 concentration, and expressing this response as carbon concentration. All technologies must differentiate between the inorganic carbon, which may be present in the water, from sources such as the ones dissolved CO2 and bicarbonate, and the CO2 generated from the oxidation of organic molecules in the sample. One approach used to measure TOC involves subtracting the measured inorganic carbon (IC) from the measured total carbon (TC), which is the sum of organic carbon and inorganic carbon:
In Dar Al Dawa laboratories, Elemental equipment was used to estimate the TOC in the retorted water specimen. The test results from the water sample have shown that the water contained 2010 mg per liter of TOC. Dobson et al. in their study of Rundle oil shale have reported 5000 ppm of TOC material in their workemploying GC for analysis. The water sample was taken from Fischer Assay apparatus. In a different study reported by Syamsiah et al. the retorted water was found to contain more than 13,000 mg/liter. In another work of [
Phenol is a colorless-to-white solid when pure; however, the commercial product, which contains some water, is a liquid. Phenol has a distinct odor that is sweet and lasting. Most people begin to smell phenol in the air at about 40 parts of phenol per billion parts of air (ppb), and they begin to smell phenol in the water at about 1 - 8 parts of phenol per million parts of water. These levels are lower than the levels at which adverse health effects have been observed in animals that breathed air containing phenol, or drank water containing phenol. Phenol evaporates more slowly than water, and a moderate amount can form a solution with water.
A number of effects from breathing phenol in the air have been reported in humans. Short-term effects reported include: respiratory irritation, headaches, and burning eyes. Chronic effects of high exposures included: weakness, muscle pain, anorexia, weight loss, and fatigue; effects of long-term low-level exposures included: higher chance of developing respiratory cancer, heart disease, and effects on the immune system.
The retorted water content of phenol was determined in Dar Al Dawa laboratories using HPLC. The tested water was found to contain 64 mg/liter. A study by AlJaradin retorted water obtained from Ellajjun oil shale retorting has reported 29 mg/liter. A similar study by Venardos et al. has reported 14.2 gm/liter of phenol in retorted water obtained from in-situ and above ground retorting. The test is performed on a sample and repeated three times. Dobson et al. [
It can be seen that the phenol content of Sultani oil shale is comparable with Utah oil shale, and less than that reported by Kekisheva et al. [
Long-term exposure to arsenic in drinking water can cause cancer in the skin, lungs, bladder, and kidney. It can also cause other skin changes such as thickening and discoloration. The likelihood of effects is related to the level of exposure to arsenic and in areas where drinking water is heavily contaminated, these effects can be seen in many individuals in the population. Increased risks of lung and bladder cancer and skin changes have been reported in people ingesting arsenic in drinking water at concentrations of 50 µg/liter, or even lower.
Exposure to arsenic in the workplace by inhalation can also cause lung cancer. The likelihood of cancer is related to the level and duration of exposure. Increased risks of lung cancer have been observed at exposure levels that add up to more than 750 (µg/m3) yearly.
In regards to the possible method by which arsenic causes cancer, the evidence in humans indicates that arsenic can cause damage to whole chromosomes, but it does not appear to cause damage to the individual genes.
The metal arsenic, abbreviated as As, was detected in serval oil shale retorted water samples. In the present work, the amount of Arsenic metal was found to be 0.18 mg/liter. AlJardain [
After a thorough review on phosphate related literature, it is reported that excessive phosphate consumption leads to a higher mortality rate in patients with renal disease. Free phosphate, as found in food additives, is entirely absorbed in the gastrointestinal tract, and research has demonstrated that individuals with renal disease have significant concentrations of elevated phosphate. Recent studies have demonstrated that phosphate also seems to damage blood vessels and induce aging processes. Many types of fast food contain phosphate additives, and fast foods are generally predominately consumed by those of lower socioeconomic status. It also appears that excessive phosphate consumption is associated with increased prevalence of cardiovascular diseases in the general population.
Tests were performed in Stannous chloride reported 35.7 gm/liter in the present work. While Dean et al. [
Sulfate is a substance that’s found naturally in drinking water. Health concerns regarding sulfate in drinking water have been raised because of reports that diarrhea may be associated with the ingestion of water containing high levels of sulfate. Groups within the general population that may be at greater risk from the laxative effects of sulfate when they experience an abrupt change from drinking water with low sulfate concentrations to drinking water with high sulfate concentrations are of particular concern. Sulfate in drinking water currently has a secondary maximum contaminant level (SMCL) of 250 milligrams per liter (mg/L), based on aesthetic effects (i.e., taste and odor).
The test equipment for determining sulfate in the present work is Ion Chromatography in Jordan Water Authority laboratories. The reported value is 5022 mg/liter for retorted water obtained from retorting Sultani oil shale. A similar study by Matouq et al. [
Al-Harahsheh, S., Al-Ayed, O., Amer, M. and Moutq, M. (2017) Analysis of Retorted Water Produced from Partial Combustion of Sultani Oil Shale. Journal of Environmental Protection, 8, 1018-1025. https://doi.org/10.4236/jep.2017.89064