Adsorption in combination with ozonation for the treatment of textile waste water: a critical review

doi:10.1007/s11783-017-0899-5

Front. Environ. Sci. Eng.

2017, Vol. 11

Issue (1) : 8 https://doi.org/10.1007/s11783-017-0899-5

REVIEW ARTICLE

Adsorption in combination with ozonation for the treatment of textile waste water: a critical review

Shraddha Khamparia¹(

),Dipika Kaur Jaspal²

¹. Symbiosis Centre for Research and Innovation, Symbiosis International University, Lavale, Pune-412115, India
². Symbiosis Institute of Technology, A Constituent of Symbiosis International University, Lavale, Pune-412115, India

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Abstract

A combination of adsorption with ozonation proved best for dye removal.

Toxicity of the textile effluents can be remarkably reduced by combined method.

Wide scope for choice of natural materials for treatment of textile dyes.

Intrusion of synthetic textile dyes in the ecosystem has been recognized as a serious issue worldwide. The effluents generated from textiles contain large amount of recalcitrant unfixed dyes which are regarded as emerging contaminants in the field of waste water study. Removal of various toxic dyes often includes diverse and complex set of physico-chemical, biological and advanced oxidation processes adopted for treatment. Adsorption in itself is a well-known technique utilized for treatment of textile effluents using a variety of adsorbents. In addition, ozonation deals with effective removal of dyes using high oxidising power of ozone. The review summarizes dye removal study by a combination of ozonation and adsorption methods. Also, to acquire an effective interpretation of this combined approach of treating wastewater, a thorough study has been made which is deliberated here. Results asserts that, with the combined ability of ozone and a catalyst/adsorbent, there is high possibility of total elimination of dyes from waste water. Several synthetically prepared materials have been used along with few natural materials during the combined treatment. However, considering practical applicability, some areas were identified during the study where work needs to be done for effective implementation of the combined treatment.

Keywords Adsorption Ozonation Catalytic Ozonation Textile dyes Mineralization

Corresponding Author(s): Shraddha Khamparia

Issue Date: 06 January 2017

Cite this article:

Shraddha Khamparia,Dipika Kaur Jaspal. Adsorption in combination with ozonation for the treatment of textile waste water: a critical review[J]. Front. Environ. Sci. Eng., 2017, 11(1): 8.

URL:

https://academic.hep.com.cn/fese/EN/10.1007/s11783-017-0899-5
https://academic.hep.com.cn/fese/EN/Y2017/V11/I1/8

Tab.1 Researches considering comparison between Adsorption, Ozonation and their combination

references	catalyst	dyes	color removal/%	COD removal/%	time /min	TOC removal /%	pH	catalyst dosage	O₃ dosage	initial color conc.
Avramescu et al. [39]	metal oxides	acid red 88	100	68	~20	64	11	2 g?L^-¹	20 L?h^-¹	500 mg?L^-¹
Feng et al. [62]	saturated AC	Biotreated effluent	-	-	-	-	-	-	-	-
Wu et al. [63]	AC from brewing yeast by sodium carbonate activation and AC suppoted by cobalt	Methylene blue	-	-	120	-	6	0.8 g	65 mg?L^-¹ @ 0.3 m³?h^-¹	1000 mg?L^-¹
Gul et al. [64]	GAC	reactive red 194 and reactive yellow 145	>95	-	30	50	6.5	30 g?L^-¹	28 mg? min^-¹ @ 0.8 l min^-¹	100 mg?L^-¹
Gholami-Borujeni et al. [65]	GAC	basic blue 9	95	-	5	48	10	2g?L^-¹	2.66 g?h^-¹	1500 ADMI
Pachhade et al. [66]	metal ions	procion red MX-5B	100	94	15	-	11	1.0 g?L^-¹	260 mg?h^-¹ @ 75 L?h^-¹	250 mg?L^-¹
Wu et al. [67]	MnO₂	C.I. reactive red 2 and C.I. acid orange 6	>90	-	120	-	-	3 g	500 mL?min^-¹	40 ppm
Li et al. [68]	Cu-Mn/Al₂O₃	acid red B	99.35		20	54.38	8.3	4 g?L^-¹	4.26 mg?min^-¹	250 mg?L^-¹
Khuntia et al. [69]	metal ions	congo red	99	-	20	83	3	0.2 mM	1.7 mg?s^-¹	10 mg?L^-¹
Mehta et al. [70]	metal oxide	reactive black 5	99	-	60	-	7	-	-	-
Wu et al. [71]	Fe loaded AC	crystal violet	>96	57	30	-	7	2.5 g?L^-¹	4.44 mg?min^-¹ @ 300 mL?min^-¹	400 mg?L^-¹
Polat et al. [72]	Per fluoro octyl alumina	real waste water	75.1	40.2	-	34.8	10	300 g	0.9±1 mmol?L^-¹ gas	-
Sun et al. [73]	Mn-Fe-ceramic honeycomb	reactive dye	98.5	-	60	-	6.92	2.87-3.26 g	2.0 g?h^-¹	200 mg?L^-¹
Asgari et al. [74]	bone char	reactive black 5	~100	-	40	-	10	-	5g?h^-¹ @ 4 L?min^-¹	-
Liu et al. [75]	Fe–Cu–O catalyst	acid red B	>90	70	60	-	6.8	1 g?L^-¹	30 mg?min^-¹	200 mg?L^-¹
Orge et al. [76]	Lanthanum-based perovskites	C.I. reactive blue 5	~100	-	15	~100	5.5	-	50 g?m^-³ @ 150 cm³?min^-¹	50 mg?L^-¹
Hassan and Hawkyard [77]	AC, hydrated alumina and ferric oxide supported on Si	simulated and real effluent	>89	-	1.66	-	4	100 mg?dm^-³	1.756 g?h^-¹ @ 24 dm³?h^-¹	120 mg? dm^-³
Faria et al. [78]	AC, cerium oxide and a ceria-AC composite	C.I. reactive blue 5, C.I. acid blue 113 and C.I. reactive yellow 3	100	-	10	85	5-6	350 mg	50 g?Nm^-³ @ 150 cm³?min^-¹	50 mg?L^-¹
Pirgalıoglu and Ozbelge [79]	powdered copper sulphide (CuS)	acidic red 151, Remazol brilliant blue-R and reactive black-5	-	-	80	>90	10	0.1 g?L^-¹	115 mg?min^-¹ L^-¹	100 mg?L^-¹
Chen et al. [80]	recyclable magnetic catalyst	reactive black 5	100	-	5	94.3	3	0.1 g?L^-¹	20 mg?L^-¹ @ 2.4 L?min^-¹	50 mg?L^-¹
Zhu et al. [81]	reusable catalyst chip	basic yellow 87	99	60	30	240	6.6	10.6875 g	500 ppm @ 0.5 L?min^-¹	216 ppm
Lu et al. [82]	MgFe₂O₄	acid orange II	>90	-	40	48.1	4.6-9.6	0.1 g?L^-¹	5.0 mg?L^-¹ @ 0.1 L?min^-¹	50 mg?L^-¹
Moussavi and Mahmoudi [83]	MgO nanocrystals	reactive red 198	100	61	9	-	8	5 g?L^-¹	0.2 g?h^-¹	200 mg?L^-¹
Pugazhenthiran et al. [84]	Au-Bi₂O₃/Bi₂O₃ nanocatalysts	acid orange 10	-	-	30	47	~5.8	1 g?L^-¹	2 mg?L^-¹	1 mM
Zhang et al. [85]	(Fe⁰-CNTs)	Methylene blue	100	-	16	89	3 and 9	13.6 mg	5 g?h^-¹ @ 5 L?min^-¹	0.025 mM
Qu et al. [86]	Carboxylated carbon nanotubes	Indigo	100	-	20	35.1	4	8 mg?L^-¹	140.6 mg?L^-¹ @ 36 mL?min^-¹	100 mg?L^-¹
Hu et al. [87]	carbon aerogel supported with copper oxide	C.I. reactive black 5	85	57	60	-	10.6	1 g	4.0 mg?min^-¹	800 mg?L^-¹

Tab.2 Catalytic Ozonation method for treatment of textile dyes

Tab.3 Natural materials used during Catalytic Ozonation treatment for removal textile dyes

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