The present examination investigates the pertinence of response surface method related to the Box-Behnken Design to statistically streamline the electro coagulation system to ejection of Dicofol pesticide from misuse water. The effect of three parameters: electrolysis time (20-180 min), pH (3-11), voltage (3-19 volts), was considered. The quadratic backslide show displayed a respectable relationship amongst foreseen and trial values (R2 = 0.98). ANOVA studies (p-regard) attested adequacy of backslide illustrate. Likewise, a low value (0.18) of coefficient of assortment showed a more elevated amount of precision and relentless nature of examinations. Response surfaces showed a colossal impact of electrolysis time, voltage and pH on the removal of Dicofol from liquid course of action. The perfect conditions obtained were electrolysis time (124 min), Voltage (15 volts) and pH (5.2) to fulfill departure of Dicofol. The proposed plot associations may ended up being a profitable mechanical assembly in arranging the business plant for the electro coagulation process.

1.
Ceron
,
J. J.
, et al. "
Endosulfan isomers and metabolite residue degradation in carnation (dianthus caryophyllus) byproduct under different environmental conditions
."
Journal of Environmental Science & Health Part B
30
.
2
(
1995
):
221
232
.
2.
Sarkar
,
Soumik
,
A.
Satheshkumar
, and
R.
Premkumar
. "
Biodegradation of Dicofol by Pseudomonas strains isolated from tea rhizosphere microflora
."
Int. J. Integr. Biol
5
.
3
(
2009
):
164
166
.
3.
Abhilash
,
P. C.
, and
Nandita
Singh
. "
Pesticide use and application: an Indian scenario
."
Journal of hazardous materials
165
.
1
(
2009
):
1
12
.
4.
Errami
,
M.
, et al. "
Oxidation of the Pesticide Dicofol at Boron-Doped Diamond Electrode
."
Journal of ChemicaActa
1
.
1
(
2012
):
44
48
.
5.
Sarkar
,
Soumik
,
A.
Satheshkumar
, and
R.
Premkumar
. "
Biodegradation of Dicofol by Pseudomonas strains isolated from tea rhizosphere microflora
."
Int. J. Integr. Biol
5
.
3
(
2009
):
164
166
.
6.
Wang
,
Ziyuan
, et al. "
Reaction mechanism of dicofol removal by cellulase
."
Journal of Environmental Sciences
36
(
2015
):
22
28
.
7.
Zhai
,
Zihan
, et al. "
Effects of metal ions on the catalytic degradation of dicofol by cellulase
."
Journal of Environmental Sciences
33
(
2015
):
163
168
.
8.
Ahmad
,
Tanweer
, et al. "
Removal of pesticides from water and wastewater by different adsorbents: A review
."
Journal of Environmental Science and Health, Part C
28
.
4
(
2010
):
231
271
.
9.
Rajan
,
Aswathy
,
Sanju
Sreedharan
, and
V.
Babu
. "
Solvent Extractionand Adsorption Technique for the Treatmentof Pesticide Effluent
."
10.
Mohammed
,
Sibhi
, and
P. A.
Fasnabi
. "
Removal of Dicofol from Waste-Water Using Advanced Oxidation Process
."
Procedia Technology
24
(
2016
):
645
653
.
11.
Zhao
,
Limian
, and
HianKee
Lee
. "
Application of static liquid-phase micro extraction to the analysis of organochlorine pesticides in water
."
Journal of Chromatography A
919
.
2
(
2001
):
381
388
.
12.
Khandegar
,
V.
, and
Anil K.
Saroha
. "
Electrocoagulation for the treatment of textile industry effluent–a review
."
Journal of environmental management
128
(
2013
):
949
963
.
13.
Behloul
,
M.
, et al. "
Removal of Malathion pesticide from polluted solutions by electrocoagulation: Modeling of experimental results using response surface methodology
."
Separation Science and Technology
48
.
4
(
2013
):
664
672
.
14.
Acharya
,
Sanigdha
, et al. "
Statistical Optimization of Electrocoagulation Process for Removal of Nitrates Using Response Surface Methodology
."
Indian Chemical Engineer
(
2017
):
1
16
.
This content is only available via PDF.
You do not currently have access to this content.