Activated coal obtained from mango residues is an alternative for the valorisation of these wastes for applications. This work focuses on the production of a new adsorbent from mango residues collected in the urban common of Mamou (Republic of Guinea) by chemical activation with potassium hydroxide. To do this, the different rates: humidity, cinders, volatile matter, fixed carbon et iodine indices before activation and after activation at 400°C and 700 °C were determined which are: (6.28%; 0.97%; 73.80%; 25.23%) respectively. The best indices were found in powdered activated coal compared to grain activated coal for the concentrations used. This study can be an alternative bio-adsorbent for the urban community of Mamou in water treatment.
Mango is one of the fruits from the Anacardiaceae family, the most cultivated, accessible and consumed in the tropical and subtropical regions because of its excellent flavor and high nutritional value [
According to a report by the Food and Agriculture Organization Statistics (FOASTAT), West African countries produced 810,000 tons of mangoes in 2010 [
This study was carried out in the prefecture of Mamou, which is considered as a crossroads city of the Republic of Guinea. It is located 270 km from Conakry the capital, between 9˚54' and 11˚25' North latitudes and 11˚25' and 12˚26' West longitudes with an area of approximately 8000 km2 for a population of 318.738 inhabitants. According to the 2014 census, Mamou is one of the administrative regions of the Republic of Guinea and the region of Fouta Djallon called “water tower” of West Africa. The prefecture of Mamou shelters the sources of the three great rivers of the region: Bafing (Senegal River), Konkouré and Kaba. It is located to the east by the prefectures of Dabola and Faranah, to the west by the prefecture of Kindia to the north by the prefectures of Dalaba and Tougué to the south by the Republic of Sierra Leone. Mountainous area with lateritic plateaus of bowés, hills with steep slopes interspersed with plains and fairly fertile lowlands. The average altitude varies from 400 to 800 m from south to north (
The Laboratory of Chemistry of the Superior Institute of Technology of Mamou, the laboratory of Analytical chemistry of the Gamal Abdel Nasser University of Conakry, and the laboratory of the National Office of Quality Control of Matoto Conakry, served as a framework for studies.
The mango residues composed of mango nuts used for this analysis were collected in the big market of Mamou, sector Dinguirawi, in the prefecture of Mamou from 15 to 31 March 2022 (
Before analysis, the nouts were sorted to remove bad and forein matter, then washed and dried at room temperature in the laboratory for 48 hours. Then the second drying at 105˚C in the oven for 30 minutes removed residual contaminants. They were then crushed and subdued. Particles of granulometry size between 1.5 mm and 3.5 mm have been selected for the manufacture of our coals; those with a diameter less than or equal to 1 mm were used for immediate analyzes to determine certain constituents of the biomass.
· The oven;
· The carbonizer;
· The desiccator;
· The balance;
· Trays;
· Kiln;
· The spectrophotometer;
· The distiller;
· Glassware;
· Potassium hydroxide solution;
· Iodine;
· Hydrochloric acid.
Starch ampoi, sodium thiosulphate pentahydrate were obtained from the chemistry laboratory of the Institute Supérieur of Technology of Mamou and used without purification.
We used a carbonizer from the local manufacture of the department of mechanical construction and manufacturing of the Institute Supérieur of Technology of Mamou. Carbonization or pyrolysis is the thermal decomposition of the shells of mango pits to produce coal. It occurs in an enclosed space where the air inlet is controlled so that the shell is not burned and reduced to ashes, but turned into husk coal. It includes the following parts: an outer cylinder, an inner cylinder, the chimney between the two cylinders and the combustion zone (
1) Ignition
The fuel load in the combustion zone is burned through the lower air inlets of the unit. Enter the maximum of air in the furnace. The temperature in the combustion zone rises to 200˚C. At this temperature, the mango kernel shells in the inner cylinder lose their moisture (endothermic period where the reactions are provoked by a heat input corresponding to the drying process during which some volatile compounds are carried away by the water vapor. The rest of the furnace rises in temperature. This phase is short; it only serves to form the carbonization front inside the oven).
2) The dehydration
The air inlets are reduced; the mango kernel shells release the water they contain. From 200˚C, the less stable constituents of the shells decompose. And the residue of the shells is transformed into roasted shells.
3) The carbonization
From 280˚C, another reaction occurs which is exothermic, which raises the
temperature without external contribution until 350˚C - 380˚C. The phenomenon of combustion is still necessary to maintain the process. A small amount of air is therefore necessary. The average temperature during this phase is between 280˚C and 380˚C. The residue becomes coal, but with a carbon content of less than 80%. If heating is continued until 700˚C to 900˚C, coal for the industry is produced.
To characterize the biomass, we determined some parameters such as moisture, ash, volatile matter and fixed carbon rates.
The moisture content of mango nuts was determined by the method of complete desiccation in the oven between 100˚C - 105˚C for 3 hours to the constant weight according to the (formula) [
H % = P 1 − P 2 Pe × 100
wherein “H%” represents Percentage of humidity; P1; P2 = Weight of capsule and sample before and after drying; Pe = Weight of the test portion.
Ash is a gray or whitish colored residue obtained by the complete incineration of solid biofuels to constant mass. The method consists of incinerating a crushed and sieved biomass sample at a constant temperature of 815˚C until a constant mass is obtained. And the ash content was calculated using the following (Formula).
TC = m 3 − m 1 m 2 − m 1 × 100
TC = center rate; m3 = mass of crucible + sample after cooling; m2 = mass of crucible + sample before heating; m1 = mass of empty crucible and according to the A.O.A.C method (1975).
ProcedureTake a quantity of each sample and introduce it into a previously tared crucible. The crucible and sample assembly are placed in a muffle furnace at 815˚C for 48 hours. After incineration, remove the assembly from the furnace and place it in a desiccator until completely cooled. Then proceed to weigh [
The percentage of volatile matter (%VM) is determined by the loss of mass in moisture when the biomass is heated to 900˚C for 7 min without contact with air under standard conditions.
ProcedureInto a translucent quartz crucible of known weight (M1), introduce, with uniform distribution, 1 g ± 0.1 g of sample. Determine the weight of the container with the sample (mass M2). Then place the whole (crucible + sample) in the oven at 900˚C for 7 mn. Remove from the oven then cool for 10 mn in a desiccator, determine the weight M3 (mass M3) according to the (formula) [
MV = M 2 − M 3 M 2 − M 1 × 100
MV = volatile material; M2 = mass of crucible + sample before heating; M3 = mass of crucible + sample after cooling; M1 = mass of empty crucible.
Fixed carbon is the carbon remaining after the removal of volatile matter and ash. It is expressed in percentage of mass and given by (the formula):
CF = 100 − ( % MV + % TC )
The characterization of activated carbons was carried out in terms of the iodine index (an indicator of the capacity of the carbon to adsorb low molecular weight molecules). This characterization allowed us to evaluate the adsorbing properties of our activated carbons. For the production of our activated carbons, we used the process of physical activation (carbonization) to create pores in the carbon that will increase its porosity and its adsorption capacity [
| Samples | T˚ of carbonization (en ˚C) | Impregnation rate | Agent activant | Carbonization time |
|---|---|---|---|---|
| Samples 1 | 400 | 5.0 g coal/50ml | KOH 10−1 N, 3 × 10−1 N et 5 × 10−1 N | 1 h 30 mn |
| Samples 2 | 700 | 5.0 g/50ml | KOH 10−1 N, 3 × 10−1 N et 5 × 10−1 N | 1 h 30 mn |
Our study gave us the following results: this biomass, presents rates of moisture (6.28%); ash (0.97%); volatile matter (73.80%) and fixed carbon (25.23%) that are represented in (
The value of the moisture content is 6.28% which would be higher than that found by [
shows that the biomass used is composed of a majority of organic matter; it denotes non-contamination in inorganic products of mango kernel shells [
In this work, we set up a procedure of valorization of the residues of mangoes thrown everywhere in the urban commune of Mamou (Republic of Guinea) to make materials of great utility.
The results of the analysis gave the following values of rates of moisture, ash, volatile matter and fixed carbon: 6.28%; (0.97%); (73.80%); (25.23%) respectively. The iodine indices after activation to temperatures of 400˚C and 700˚C for powdered coal gave the following values: 1354.0 mg/g to 1716.5 mg/g and 2459.5 mg/g to 2546.5 mg/g. Similarly, for granular coals activated at 400˚C and 700˚C, the values are 2378.7 mg/g to 2413.0 mg/g respectively. Finally, we note that powdered activated coals (PAC) have a higher iodine value than grain activated coals (GAC) for the concentrations used. This study shows that the shells of mango kernels can serve as raw materials for the production of adsorbents with porosity elevated and can be used for the removal of small particles or molecules of small molecular weight during the production of drinking water, wastewater treatment and would strongly contribute to the success of the sanitation operations of the city of Mamou organized by the authorities and NGOs to fight against environmental pollution.
The authors declare no conflicts of interest regarding the publication of this paper.
Sow, M.M., Sakho, A.M., Diallo, A. and Kante, C. (2022) Production of New Adsorbent from Mango residues Collected in the Urban Community of Mamou. Journal of Agricultural Chemistry and Environment, 11, 296-306. https://doi.org/10.4236/jacen.2022.114021