Assessment of the implementation status of best available techniques for cleaner production in the textile industry

doi:10.1007/s11783-024-1863-9

Front. Environ. Sci. Eng.

2024, Vol. 18

Issue (8) : 103 https://doi.org/10.1007/s11783-024-1863-9

Assessment of the implementation status of best available techniques for cleaner production in the textile industry

Mehmet Eren Yaman¹, Emrah Ozturk²(

), Ulku Yetis³, Mehmet Kitis¹

¹. Department of Environmental Engineering, Suleyman Demirel University, Isparta 32260, Turkey
². Department of Environmental Protection Technologies, Isparta University of Applied Sciences, Isparta 32200, Turkey
³. Department of Environmental Engineering, Middle East Technical University, Ankara 06800, Turkey

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Abstract

● The compliance status of 488 BATs was investigated in the Turkish textile sector.

● Full-scale BAT implementation ratios (IR) were evaluated under 17 headings.

● It was found that 37% of the BATs was already implemented full-scale.

● 63% of BATs was potentially to be implemented and not projected to be implemented.

● It was found that 60 BATs had lower IR values (0%–43%).

The draft Integrated Pollution Prevention and Control (IPPC) regulation mandates compliance with best available techniques (BATs) for textile manufacturers. A study in Turkish textile facilities, covering 56 units across four sub-sectors, assessed the status of 488 BATs through on-site visits and surveys. The aim was to gauge the sector’s adherence to BATs. The findings revealed that 37% of surveyed BATs were fully implemented, rising to 88% when considering potential future implementations. This suggests a strong industry inclination toward adopting BATs for cleaner production and competitiveness. The study highlighted significant BAT-related investments in the textile sector, driven by environmental concerns, regulations, customer demands, resource efficiency, competition, and cost-benefit considerations. However, the study results also indicated that there is still much work to do for the implementation of some BATs. It was found that 60 BATs had lower implementation ratios (IR: 0%–43%). Lower IR values for these BATs are mainly due to factors like specificity, high costs, long payback periods, operational difficulties, limited expertise, space constraints, customer requirements, quality concerns, operational issues, and sector-specific challenges. The study recommends similar assessments in other European industrial sectors to evaluate compliance with mandatory BATs outlined in the Industrial Emissions Directive. The insights from this study on the Turkish textile sector can serve as a valuable guide for future evaluations.

Keywords Best available techniques (BAT) Cleaner production Green Deal Integrated Pollution Prevention and Control (IPPC) Textile sector

Corresponding Author(s): Emrah Ozturk

About author:

#usheng Xing, Yannan Jian and Xiaodan Zhao contributed equally to this work.]]>

Issue Date: 30 May 2024

Cite this article:

Mehmet Eren Yaman,Emrah Ozturk,Ulku Yetis, et al. Assessment of the implementation status of best available techniques for cleaner production in the textile industry[J]. Front. Environ. Sci. Eng., 2024, 18(8): 103.

URL:

https://academic.hep.com.cn/fese/EN/10.1007/s11783-024-1863-9
https://academic.hep.com.cn/fese/EN/Y2024/V18/I8/103

BAT category	Number of BAT	BAT code	BAT description	Current BAT IR (%)
General measures	18	BATs with the highest IR
		BAT2	Training programs to raise awareness about the environment	89
		BAT5	Adopting better practices in maintenance and cleaning activities	86
		BAT6	Organizing technical training to raise awareness of employees and strengthen the technical infrastructure	82
		BAT7	Choosing machines that provide resource efficiency in the selection of machines, devices and equipment	89
		BAT11	Following new technologies and developments related to the sector	91
		BATs with the least IR
		BAT1	Establishing an environmental management system (EMS)	34
		BAT10	Using process-based monitoring systems and/or conducting cleaner production-efficiency studies periodically	46
		BAT12	Establishing an efficiency and/or sustainability unit	25
		BAT13	Preparation and effective use of necessary procedures to implement a cleaner production policy specific to the facility	38
Products produced and their quantities	5	BATs with the highest IR
		BAT21	Ensuring appropriate conditions for storing and storing raw materials	82
		BAT22	Monitoring raw material losses in production processes and taking precautions against raw material losses	77
		BAT23	Preferring substances that can provide resource efficiency (increase production performance and improve product properties) in the selection of raw materials and chemicals	84
		BATs with the least IR
		BAT19	Preferring in the selection of fiber raw materials, the environmental effects of the fiber in the previous production stages taken into account and the one with the least environmental impact	43
		BAT20	Establishing procedures that provide supplier control in raw material selection	52
Chemical use	27	BATs with the highest IR
		BAT24	Optimizing the recipes applied in production, taking into account environmental impacts	71
		BAT25	Applying and storing all chemical substances in accordance with the instructions given in the Substance Safety Data Guides (MSDS)	86
		BAT26	Preventing all chemical spills, controlling and cleaning the area if a spill occurs, and preventing chemical spills from mixing with the receiving environment and sewage system	79
		BAT29	The use of the chemical with the least risk, in cases where the use of chemicals is essential in the selection and use of chemicals	84
		BATs with the least IR
		BAT32	Applying a dry process to remove iron from the fabric before bleaching, especially in pre-treatment and dyeing processes, when using complexing agents	13
		BAT40	Use of polyether/polyester or polyether/polycarbonates, special polyol esters and special sterically hindered fatty acid esters as an alternative to conventional preparation additives containing mineral oil	23
		BAT42	Calculation of substrate-based emission factors in textile finishing regularly (at least once a year) and especially before using a new recipe or changing compounds of an existing recipe	18

Tab.1 Current BAT implementation status regarding general measures, produced products and chemical use

Tab.2 Current BAT implementation status regarding water resources, water supply and process water preparation systems

Tab.3 Current BAT implementation status regarding energy supply, steam production and distribution

Tab.4 Current BAT implementation status regarding electricity usage

Tab.5 Current BAT implementation status regarding compressed air and HVAC systems

BAT category	Number of BAT	BAT code	BAT description	Current BAT IR (%)
Pre-treatment processes	120	BATs with the highest IR
		BAT245	Using automatic equipment to control bath volume and temperature in batch-operating machines	89
		BAT249	Using water flow control devices and automatic shut-off valves in continuously operating machines	89
		BAT251	Investigating the possibilities of combining different operations in one step	78
		BAT252	Increasing washing efficiency	78
		BAT258	Appropriate collection, storage and disposal of textile waste for reuse	89
		BATs with the least IR
		BAT210	Recovery of sizing chemicals from desizing wastewater by membrane filtration	0
		BAT260	Conducting process-based energy audits and identifying potential savings points	0
		BAT273	Controlling and monitoring energy consumption	0
		BAT308	Characterization of discrete wastewater streams and evaluation of water/material recovery and reuse opportunities	0
Dyeing and printing processes	58	BATs with the highest IR
		BAT321	Use of dyes that have high adhesion to fiber	64
		BAT322	Using auxiliary chemicals that will not prevent the dyes from adhering to the fiber at a high rate	61
		BAT333	Selecting the machines most suitable for the lot sizes to be processed	61
		BAT345	Avoiding the use of dangerous carrier	63
		BAT346	Instead of organic carriers containing chlorine, use of carriers containing benzylbenzoate and N-alkylphthalimide groups, which do not contain chlorine groups, cause less odor problems in the operation and have low volatility	59
		BATs with the least IR
		BAT327	Reuse of dyeing wastewater after treatment	2
		BAT328	Reuse of washing wastewater after dyeing by membrane filtration	0
		BAT329	Reuse of washing wastewater after dyeing by adsorption	2
		BAT371	Making the printing paste feeding system more efficient and automating in flat printing machines	4
		BAT372	Reducing the paste remaining on the template by modifying the squeegees in flat printing machines	5
Finishing processes	41	BATs with the highest IR
		BAT405	Use of easy-care products that do not contain formaldehyde or have reduced formaldehyde content (< 0.1% formaldehyde content in the formulation) that create cross-linking during final treatments	50
		BAT407	Optimizing passage speeds in stenters	55
		BAT410	Removing excess water remaining on the fabric before drying by using effective squeezing processes and thus reducing the energy need for drying where technically possible	50
		BAT413	Adapting appropriate material preparation procedures	52
		BAT416	Preventing spills as a result of overflow	65
		BATs with the least IR
		BAT386	Reusing rinse water in technically possible processes without purification	11
		BAT387	Reusing the rinse water as process water after combining it with similar wastewater streams and after treatment	9
		BAT388	Evaluation of the use of relatively clean washing/rinsing wastewater for cleaning purposes	11
		BAT389	Reuse of finishing wastewater in other processes	7
		BAT390	Neutralization of finishing wastewater with alternative methods instead of sulfur/citric acid	7

Tab.6 Current BAT implementation status regarding pre-treatment, dyeing-printing and finishing processes

BAT category	Number of BAT	BAT code	BAT description	Current BAT IR (%)
Wastewater streams and wastewater treatment systems	39	BATs with the highest IR
		BAT427	Reuse of cooling water (It is possible to recycle the cooling water that does not come into contact with the product in a closed circuit and transfer the used water to a tank and reuse it in the process)	45
		BAT428	Separate collection and reuse of cooling water (Cooling water that does not come into contact with the fabric/yarn can be collected in a tank and used in processes that require hot water such as dyeing, bleaching, washing. For example: condenser-cooling water, heat exchanger water, water from compressors, etc.)	43
		BAT429	Preventing contamination risks by checking coils and cooling water quality	45
		BATs with the least IR
		BAT443	Membrane processes (Pressure membrane processes used in the treatment of textile wastewater are microfiltration (MF), ultrafiltration (UF), nanofiltration (NF) and reverse osmosis (TO))	0
		BAT444	Treatment and reuse of textile wastewater with membrane processes (Wastewater originating from the textile industry can be treated with membrane processes, respectively, following balancing and neutralization works, and the purified water taken from the RO or NF output can be directly used back in the textile industry production processes)	0
		BAT445	Treatment with membrane bioreactors (MBR) (With the MBR system, which is a combination of aerobic biological treatment and membrane process, the treatment of textile wastewater with high and complex pollution can be achieved with very high efficiency)	0
		BAT446	Membrane bioreactor (MBR) + Nanofiltration (NF) (One of the best techniques for the purification and reuse of textile wastewater is the purification of MBR effluent in the NF process. In this composite membrane configuration, the purified water at the NF outlet can be reused within the facility)	0
		BAT447	Treatment of wastewater with approximately 60% water recovery (Activated sludge + adsorption + sedimentation + flocculation/precipitation/flotation + sand filtration + activated carbon filtration + RO)	0
		BAT450	Treatment with ozonation + activated sludge system (In the treatment system where ozonation and activated sludge are used together, the effluent COD value can be reduced to 50 mg/L)	0
		BAT455	Activated sludge system + powdered activated carbon + sand filter implementation (The exit water COD value can be reduced to 20 mg/L and a good color removal efficiency can be achieved)	0

Tab.7 Current BAT implementation status regarding wastewater streams and wastewater treatment systems

Tab.8 Current BAT implementation status regarding waste gas emissions, noise and solid wastes

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