FAQ Real Tech Water
- Classification:Chemical Auxiliary Agent
- CAS No.:84-74-2
- Other Names:Dibutyl phthalate DBP
- MF:C16H22O4
- EINECS No.:201-557-4
- Purity:99.6%
- Type:PVC additives
- Usage: Polyurethane (pu),Coating Auxiliary Agents,
- MOQ:25kg/bag
- Package:200kg/drum
- Application:Plasticizer
Real Tech’s highest organics ranges are 40 A/cm, which corresponds to much higher organics levels than are present in even Real Tech’s highest organics laden applications. (DBP) formation potential. SUVA = UV 254 nm (m-1) /
Growing concerns over public health and environmental safety have intensified the focus on minimizing harmful disinfection byproducts (DBPs) in water treatment. Traditional
Formation and influencing factors of disinfection by
- Classification:Chemical Auxiliary Agent, Chemical Auxiliary Agent
- CAS No.:84-74-2
- Other Names:Elasticizer
- MF:C16H2204
- EINECS No.:201-557-4
- Purity:99%, 99%
- Type:plasticizer
- Usage: Rubber Auxiliary AgentsCoating Auxiliary Agents,
- MOQ:200kgs
- Package:200kgs/battle
- Application:Plasticizer
Note: ‘P’ stands for DBPs production; ‘∝’ stands for positive correlation; ‘()’ stands for DBP precursor; FP stands for DBP formation potential. View Large Wang et al. (2020) used
3.3 Impact on Downstream DBP Formation Potential 3.4 Transformation Products 3.5 Nitrosamines 3.6 Inorganics: Perchlorate, Chlorite, Chlorate, and Bromate 4 Ozonation
Fluorescent Dissolved Organic Matter Components as
- Classification:Chemical Auxiliary Agent
- CAS No.:84-74-2
- Other Names:liquid dbp
- MF:C16H22O4
- EINECS No.:201-557-4
- Purity:98%
- Type:Chemical auxiliary agent, Plasticizer
- Usage:Coating Auxiliary Agents, Plastic Auxiliary Agents
- MOQ:25kg/bag
- Package:200kg/drum
- Sample:Availabe
- Application:Plasticizer
- Quality control:COA ,SDS,TDS
- Delivery:Within 7-15 Days
Disinfection Byproduct (DBP) Formation Potential. Two approaches were described in the selected articles to evaluate DBP formation, which are fully reported in SI, Extracted Data. The
2.4 DBP formation potential (DBPFP) tests DBP formation potential tests were conducted to evaluate the maximum DBP formation ability of the water samples. Free chlorine was used as
Evaluation of the DBP formation potential of biocides
- Classification:Chemical Auxiliary Agent
- CAS No.:84-74-2
- Other Names:Bis(2-ethylhexyl) phthalate, Ethyl..
- MF:C16H2204
- EINECS No.:201-557-4
- Purity:99.5%Min
- Type:Plasticizer, Plasticizer DBP Dibutyl Phthalate
- Usage:Plastic Auxiliary Agents,
- MOQ:25kg/bag
- Package:200kg/drum
- Quality control:COA ,SDS,TDS
Disinfectants and preservatives used as biocides may contain or release active substances (a.s.) that can form by-products with the surrounding matrices during their
Lower potential for DBP formation by effectively removing reactive organics Real Tech’s UV254 and UV-VIS absorbance instruments provide continuous online measurement of organic matter, allowing the chemical dose
PPCP degradation by UV/chlorine treatment and its impact on DBP
- Classification:Chemical Auxiliary Agent
- CAS No.:84-74-2
- Other Names:liquid dbp
- MF:C16H22O4
- EINECS No.:201-557-4
- Purity:99.5%, 99.5%
- Type:Chemical auxiliary agent, Plasticizer
- Usage:Leather Auxiliary Agents, Plastic Auxiliary Agents, Rubber Auxiliary Agents, Textile Auxiliary Agents
- MOQ:25kg/bag
- Package:200kg/drum
- Delivery:Within 7-15 Days
PPCP degradation by UV/chlorine treatment and its impact on DBP formation potential in real waters. Author links open overlay panel Xin Yang a, Jianliang Sun b, Wenjie Fu a, Chii Shang b c, Yin Li a, Yiwei Chen a, Wenhui Gan a Science and Technology Planning Project of Guangdong Province, China (2014A020216010) and Hong Kong Research Grant
5 moles of DOC (DBP potential formation, equal to Aif + Ais,) increases with chlorine dose if total THMs and total HAAs are considered, while this is not always true for single DBP species
- Can disinfection byproduct (DBP) formation potential be evaluated?
- Disinfection Byproduct (DBP) Formation Potential. Two approaches were described in the selected articles to evaluate DBP formation, which are fully reported in SI, Extracted Data.
- What is the primary source of DBP precursors?
- NOM, commonly present in surface waters, is the primary source of DBP precursors. Effective control of DBP formation often involves the removal of NOM. Techniques such as coagulation, activated carbon adsorption, and membrane filtration are standard methods employed in drinking water treatment plants (DWTPs) to eliminate NOM.
- What are the precursors of DBP in contaminated water?
- Due to extensive water pollution, the precursors of DBPs in contaminated water sources typically consist of a mixture of autochthonous and allochthonous compounds. These include substances linked to microorganisms (such as algae and bacteria), organic matter from wastewater discharges, amino acids, and proteinaceous compounds.
- What does DBP stand for?
- [Google Scholar] [CrossRef] Chowdhury, S.; Mclellan, P.J. Models for Predicting Disinfection Byproduct (DBP) Formation in Drinking Waters: A Chronological Review. Sci.
- Are toxic DBPs formed during water treatment?
- The formation of toxic DBPs during water treatment has been comprehensively documented over the last five decades. However, the detailed mechanisms behind the formation of individual DBP compounds, the identification of emerging DBP categories, and the properties of their precursors remain critical topics of investigation.
- Is sodium hypochlorite a precursor of DBP in water?
- Wang et al. (2012a) found that sodium hypochlorite solution reacted with some pure bacterial strains to generate CF, dichloroacetonitrile (DCAN), chloral hydrate (CHD), and their brominated analogs, suggesting that bacteria may be important precursors of DBPs in water.