Abstract
Wastewater can offer a favorable solution for wastewater treatment. This work reviews series of filters with different particle sizes, namely pozzolan and sawdust, as an alternative for wastewater treatment. A permeability coefficient was determined for each filter. The biofilm was prepared by passing a stream of wastewater containing bacteria through different filters separately. The purification of wastewater was performed on the biofilm with different particles sizes. The results show an inverse relationship between the permeability coefficient and the contact time that affects the efficiency of the filtration. Filtration efficiency yield is around 85–94% for chemical oxygen demand (COD) and around 92–97% for biological oxygen demand (BOD). High efficiency in removing some minerals is also observed by bacteria. The biofilm prepared from wastewater seems to be an efficient agent to filter wastewaters in particular rural areas. The formation of biofilms has significantly reduced bacterial activity and heavy metal content.
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Introduction
The world has become threatened with war, especially in the Middle East, due to the scarcity of clean water resources and the increasing demands for it. Requirements for clean water have increased with population growth, rapid urbanization, misuse of water resources and climate disruption creating a global issue of great concern. Of the seven billion people globally, over 15% do not have access to adequate freshwater for a healthy life. Increasing water contamination from the discharge of water-borne pathogens, inorganic pollutants, such as arsenic, selenium and heavy metals (e.g., cadmium, lead, mercury and chromium), chemicals used in agriculture, human and animal pharmaceutical derivatives and endocrine disrupters has exacerbated the problem (Sheikh et al. 2019). Estrogens are one of the micro-pollutants in wastewater which are excreted by all humans and animals. These estrogen hormones have detrimental effects on water living organisms (Roudbari and Rezakazemi 2018). The treatment of wastewater is considered as a major priority due to the lack of natural sources of water. Organic wastes are serious problem of wastewater; different techniques and methods are used to purify the wastewater from organic and inorganic pollutants. These pollutants are produced from distillery, paper, textile and tannery effluents…etc. Biofilm is one of the most important biological processes of waste organic treatment (Omri et al. 2013). Successful applications of this technology have been reported in wastewater treatment, petrochemical, textile and tobacco industries (Leiknes and Degaard 2001; Cogan and Keener 2004). There are several benefits of using biofilm in wastewater treatment system in comparison with suspended growth systems, such as flexible procedures, smaller space demand, lower hydraulic retention time, increased resiliency, higher biomass retaining period, increased active biomass clusters, improved recalcitrant substance degradation as well as decreased rate in microbial proliferation (Shahot et al. 2014). Apart from that, the application of biofilm systems also increases the ability to control the frequency of reaction and population mechanism (Borkar et al. 2013). The Biofilm is formed and grown through a five-stage process (Cogan and Keener 2004). The application of fixed and moving bed processes is distinguished by the quality of the support components on which biofilm is configured on static platforms such as rocks, plastic profiles, sponges, granular carriers or membranes. Membrane bioreactor (MBR) for wastewater treatment is an effective process which can be used for municipal and industrial wastewaters (Rezakazemi et al. 2018a). Also, large quantities of industrial wastewater are produced annually in the world and there are many methods of treatment including ultrasound, the most important of which is biological treatment through the biological membrane (Rezakazemi et al. 2018b). This project can be embodied in the field especially in small communities such as villages, rural areas and even small cities. The main subject of this attempt is a comparison study of the efficiency between two natural materials as biofilm filter of bacterial and heavy metals.
Materials and methods
Study materials
Wastewater
Wastewater samples were collected after physical treatment from the Karma wastewater treatment plant (Oran—Algeria).The different experimental work was based on the physicochemical and bacteriological analyses carried out at the level of the laboratory of Water and Sanitation Society of Oran (SEOR), Laboratory Organic Synthesis, Physical–Chemical and Environment (Univ. USTO-MB) and Laboratory Materials, Soil and Thermal (Univ. USTO-MB) (Tables 1, 2).
Pozzolan
Pozzolan was obtained from natural deposits in northwest of Algeria (Bouhamidi Source situated at about 100 km from Oran). Different chemical composition and characteristic properties of pozzolan are presented in Tables 3, 4 and 5.
Wood sawdust
Wood sawdust is a solid residue, which is generated in the timber industry (Couto et al. 2012).The result of general analysis for broken wood from different trees under normal conditions shows the following composition: 40% of water, 1% of organic solids or ash and 59% of the elements capable of inflammation or oxidization. These elements are in dissimilar kinds of wood as: 29.5% carbon, 3.5% hydrogen, 26% oxygen and nitrogen (Meniai 2012).
Soils nature has a big effect on the ash’s chemical composition that forms it, because nature and minerals quantity that form the ash differ from a place to another (in trees’ different parts) with different parts in trees. These are also variation depending on seasons.
Preparation of materials
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Grinding and sifting pozzolan to obtain diameters ranging between 5–8 mm and 8–12.5 mm.
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Sifting the sawdust to obtain the diameters between 5–8 mm and 8–12.5 mm.
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The above materials are washed with deionized water and dried to avoid any blockages caused by very small granules.
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The permeability coefficients (k) are calculated (fixed charge of free surface) for pozzolan and sawdust for different diameters (5–8 and 8–12.5) mm, and the results are shown in Table 6.
The equipment used for this experiment is given as follows:
Wastewater basin.
A small water pump.
Connecting pipes diameter of 5 mm.
Water sprinkler that allows the water to be sprayed evenly on the surface of the material.
The biofilter model has the following dimensions:
Cylinder height of 45.5 cm; inside diameter of 11.5 cm; outer diameter of 12.5 cm; and surface area of 103.81 cm2. The bottom of the cylinder is a perforated aluminum that allows the passage of water and air. The height of the material inside is 30 cm.
Flow meter is fixed to a rate of 1.4 cm3/s.
Phase I Biomembrane culture
The wastewater used in this study is brought from the municipal wastewater treatment plant, and it has beforehand undergone a physical treatment (P1 and S1). The air bubbles are removed from the tank that contains the wastewater to prevent any oxidation or other interactions. The biofilms are prepared by passing the wastewater through different materials (pozzolan and sawdust) under different diameters of 5–8 mm and 8–12.5 mm separately. The wastewater is mixed with a solution of glucose (1 g/l) to feed and increase the bacteria population. The mixture was passed into a glass cylinder with a different material height of 30 cm separately under a flow rate of 1.4 cm3/s. The whole system is left in rotation in a closed circle for 8 h/day to provide oxygen to bacteria. After that, the whole system is brought to the temperature of 37 °C in an oven for the remaining hours. The operation is repeated daily until 10 days (Fig. 1).
Phase II Measuring treatment yield
Raw wastewater (P2 and S2) is passed into the biofilm prepared with different diameters under the flow rate of 1.4 cm3/s and speed of 0.22–0.44 cm/s. The BOD and COD of wastewater are measured before and after the treatment (Table 6).
Phase III Measuring the concentration of metal removal
We took diameters of 5-8 for both sawdust and pozzolan each separately as they produced the best yield of BOD and COD. As shown in Table 6, we measured physicochemical properties as well as heavy metal concentrations in addition to bacterial activity before and after the wastewater treatment in the model (Table 7; Fig. 2).
Results and discussions
The speed is determined between 0.8 and 1.6 m/h that is equal to 0.22–0.44 cm/s. After doing all the tests, we came up with the following results.
As results, it is noticed that the effect of particle size in the same material plays an important role in the yield of BOD and COD after treatment. The particle size ranging between 5 and 8 mm gives a yield greater than that given by 8 and 12.5 mm. These results are in agreement with the permeability coefficient; the larger the particle size, the less friction and contact time between bacteria and water. This leads to a higher BOD and COD after treatment (Figs. 3, 4). In the case of the continued treatment during days or weeks for the diameters ranging between 5 and 8 mm, it is noticed that the thickness of filter particles increases due to the significant breeding of bacteria and therefore the amount of oxygen entering the natural filter will be reduced, thus reducing the yield (Stoodley et al. 1998; Heydorn et al. 2000); as confirmed by microscopically measured physical dimensions and visual comparison, the biofilms can take over 10 days to complete the biofilm structure. In our case, this duration was reduced by adding a solution of glucose (1 g/l) and the whole system is brought to the temperature of 37 °C in an oven for the remaining hours to accelerate the bacteria growth. In the case of particle size distribution ranging between 8 and 12.5 mm, the duration of occlusion is longer than that when the particle size is ranging between 5 and 8 mm, which leads to the enhancement in cycle life of the filter. On the bases of the treatment yield by using the same diameters for these three materials, the obtained results present a high order of magnitude around 90%. The slight difference can be attributed to the experimental error and the elemental composition of the filter. It is found that the permeability coefficient in the sawdust gives a significant increase when the particle size increase compared with the pozzolan. In the case when pozzolan and sawdust are mixed in the same proportion and with different diameters 8–12.5 mm and 5–8 mm, respectively, the treatment yield of BOD and COD is still in the same order of magnitude around 90%. It is concluded that the nature of the natural filter plays no role in improving the yield of BOD and COD. In contrast, the particle sizes give significant difference in the treatment efficiency of BOD and COD in favor of the small particle size. Within the framework of environmental conservation policy and the decrease in treatment process cost, it is preferable to use industrial waste such as sawdust as filter.
The COD and BOD yields obtained after treatment by using different filters with different particle sizes (Figs. 3, 4) give values under the standard values equal to 120 mg/l for COD and 35 mg/l for BOD, respectively, according to the Ministry of Water Resources of Algeria (Algerian Official Gazette No. 26, issued on April 23, 2006).
Figure 5 monitors the influence of particle size of different biofilters depending the contact time. It is noticed that when the particle size increases, the contact time of wastewater and the biofilter decreases. This can be explained by the relationship between permeability coefficient and particle size; when the particle size increases, the permeability coefficient increases. De Beer et al. (1994) demonstrated that the channels surrounding the cell clusters could increase the supply of oxygen (and other nutrients) to bacteria within the biofilm, thus relating structure to function. But the contact time decreases and thus the treatment yield decreases.
Figure 6 displays the results of treatment yield versus the particle sizes. As results, both BOD and COD yields decrease with the increase in particle size. These results can be explained by the statement found by De Beer et al. (1994).
The main goal of this study was to produce an effluent of better quality than that required by treatment standards.
The concentration of different parameters was periodically determined in the inlet and outlet of the biofilm bed, and then removal efficiency was calculated (Zhao and Wu 2018). Analysis of the removal results (Phase III) is shown in Table 7.
Results show that concentration of different element analyses decreased between inlet and outlet, following the biofilm treatment. It can be seen that the filters effectively reduced the different bacteriological and heavy metal elements and provided desired treatment.
Compared to the normative values (> 6.5 and < 8.5), the urban rejection of Oran (Algeria) differs between 7.16 and 8.03. The waters have a slightly basic to basic character. It indicates absence of strongly acidic or alkaline spillages (Boualla 2014).
Temperatures between 22.5 and 28 °C (after or before treatment) never exceeded the recommended limit value (30 °C—Algerian Official Journal, 2006). The hottest waters are those of the Oran (Algeria) urban discharge: 28 °C (S1).
The value of suspended solids measured after treatment exceed the national standard (Executive Decree 06-141 of April 19, 2006/Algerian Official Journal/23-04-2006) as the limit value for SS in liquid effluents (household, industrial and agricultural) a concentration of 35 mg/l (with values between 41 and 75 mg/l) (Table 7). For the Oran (Algeria) urban effluent before treatment, only the P1 and S2 discharges comply with the standard (20–31 mg/l).
The comparison of our results with those of other studies carried out previously on the Oran littoral (Houma et al. 2004) shows a considerable decrease in the concentrations of the MES. In fact, in June 1998, the measured values reached 1885 mg/l at the level of the discharge and 1650 mg/l at 5 m toward the open sea. The evolution observed is the consequence of the recent efforts made by the public authorities in the treatment of wastewater (Remili and Kerfouf 2013).
In regard to the content of heavy metals, no value substantially exceeds the normative limit. Except in phase III, there was one outlier within: - Pb (pozzolan biofilm: P3-0.8 mg/l; S2-2.04 mg/l). This is due to the substantiation of the phosphate contents. As mentioned by Ruby et al. (1994) and Shi and Erickson (2000), the use of phosphates is considered an inexpensive and highly effective method for the treatment of lead-contaminated soils. Also, on these same samples, the nickel concentrations also fluctuate a lot, from 2.1 to 2.4 mg/l before treatment and between 0.982 and 1.523 mg/l after treatment. But the highest values remain well above the normative limit (0.5–0.75 mg/l). Removal appears to be dependent and a function of the filter physical and chemical characteristics. Heavy metals are useful and necessary for metabolic reactions and growth of bacteria, but with minimal concentrations, such as iron, cobalt, lead and copper.
In particular, copper plays a very necessary role for the growth of bacteria, helps in the synthesis of metallic proteins, enters into the synthesis of certain enzymes and helps in the transfer of electrons to oxidation and reduction processes. However, there is a section of heavy metals that has no biological effect, but it is toxic and deadly to bacteria, even if in small concentrations such as mercury, cadmium, silver and lead. It affects microbial clusters by acting on growth, shape and biochemical reactions, which inevitably leads to a decrease in biomass and thus negatively affects purification and disinfection processes. The practice of biological treatment is feverous to suspended solids growth (Table 7). The deletion of phosphate values is based on the succession of anaerobic and aerobic phases during biological treatment (Rejsek 2002).
Bacteria play a key role in the biogeochemical cycle in the environment and are used for the bioremediation of As-contaminated groundwater. However, it is not yet known about how biofilm formations affect bacterial activities. The number of aerobic bacteria decreased with developed anaerobic conditions. Bacteria levels are decreased and scavenged by naturally occurring soil microorganisms in the pozzolan biofilm. It was associated with soils having the clay content and elevated pH values (Yaman 2003). The removal rates of bacteria were higher in the media with the finest grain sizes (pozzolan) as compared to the coarsest media under the same conditions (sawdust) (Ausland et al. 2002). Within the porous medium, there are areas where water can be trapped and immobile and therefore where water flows are zero. It is in these areas that bacteria can then diffuse and get trapped in addition to constriction areas where pores are too small to allow passage of cells (Truesdail et al. 1998, Jacobs 2007; Johnson et al. 2007).
The mechanism of absorbing the minerals
(a) The exclusion of the toxic metal by a permeability barrier:
These are nonspecific systems that prevent the entry of metal into the cell, either by alteration of membrane transport systems or by fixing the metal to the cell surface by components of the outer membrane of the wall or exopolysaccharides (Bruins et al. 2000).
(b) Intracellular or extracellular sequestration by cellular components which bind metals:
Outside a microorganism, metals can also be immobilized by complexation or precipitation. By-products of microbial metabolism such as H2S produced by sulfate-reducing bacteria or phosphate produced by Citrobacter lead to the precipitation of metals (Bruins et al. 2000).
(c) The enzymatic transformation of a metal:
The mercury resistance conferred by the sea operon is the best known example. This operon present on transposants or plasmids exists in several bacterial species. The expression of the mer operon is regulated by MerR, a protein which binds to the operator/promoter of the operon and thus prevents its transcription. In the presence of mercury, MerR activates the expression of the detoxification system (Summers 1992).
(d) Active transport by expulsion systems:
It is the majority system involved in the resistance of microorganisms to heavy metals. It involves very specific membrane proteins that export toxic metals from the cytoplasm to the outside of the cell. In bacteria, two main active transport systems can be distinguished according to the energy source: the chemiosmotic transporters and the P-type ATPases.
Chemiosmotic transporters use a membrane potential as an energy source to activate the expulsion of toxic metals (Silver and Walderhaug 1992).
Type P ATPases represent an important class of membrane proteins which serve to maintain suitable ionic conditions by active translocation of cations across biological membranes (Lutsenko and Kaplan 1995).
Conclusion
In this study, the determination of the permeability coefficient and the treatment yield of natural materials with different particle sizes is represented.
As concluded in this study, as the surface area of the material increases, the density and concentration of the biological bacterial membrane increase and thus the effectiveness and the quality of treatment increase.
The performance and effectiveness were based on the efficiency in removing the required chemical oxygen (COD) and the required biological oxygen (BOD), and we found a high removal rate estimated as 85–94% for the COD and 92–97% for the BOD. Also elimination of heavy metals was done after treatment through the proposed model.
The yield of COD, BOD and heavy metals obtained after the treatment is less than the maximum values stipulated in Algerian laws and regulations. This is evident in Tables 6, 7.
The biological treatment basins filled with natural materials such as pozzolan and sawdust are ideal, efficient and low cost for treatment of domestic wastewater. The appropriate experimental conditions such as standard flow, suitable height and the particle size of materials are suitable for bacteria growth. The biofilm formation significantly contributed to the removal of different polluted elements. The biofilters contribute to the removal of solids (Ahn and Jeongdong Choi 2016) and heavy metals. The final effluent passes through biofilm filter systems, which further treat toxic chemicals including organics and heavy metals.
The proposed process can be considered as low-cost process to treat different organic effluents released from industry.
This project can be embodied in the field, especially in small communities such as villages, rural areas and even small cities, in order to preserve the environment.
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Ouadi, B., Bendraoua, A., Boualla, N. et al. Efficiency of pozzolan and sawdust as biofilter in the treatment of wastewater. Appl Water Sci 10, 143 (2020). https://doi.org/10.1007/s13201-020-01226-y
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DOI: https://doi.org/10.1007/s13201-020-01226-y