Embodiment
Below in conjunction with specific embodiment, the present invention is further described, so that those skilled in the art more understands the present invention, but does not therefore limit the present invention.
1 roughly selects
Set up priority pollutants catalogue storehouse, formulate investigation of pollution sources plan, mainly comprise enterprise's essential information, enterprise product raw material essential information, scale wastewater treatment and pollutant emission situation etc., should also be clear that except this mode each side information of investigated pollution source comprises: the pollution source technological process of production, raw and auxiliary material relevant information, sewage treatment facility method.
Investigation of pollution sources and experimental data mainly comprise following several respects content after gathering arrangement:
(1) the pollution source technological process of production, comprises main reaction, subsidiary reaction;
(2) physico-chemical property of raw and auxiliary material and product, heavy metal emphasis considers existing forms in water and absorption degradation situation, and organic contaminant emphasis considers fusing point or sublimation point, the Octanol/water Partition Coefficients etc. of its dissolubility in water, pollutant;
(3) banking system of raw and auxiliary material and product
Product yield and raw and auxiliary material use amount are selected in: choose annual production (use amount) chemicals more than 1 ton, and removal amount is more than 1 ton but nontoxic (as sodium chloride) chemicals, precursor compound list is chosen with this condition, according to the possibility (main according to be whether there is mobility, whether have by adsorbability under whether water-soluble, normal temperature) entering aqueous phase, choose primary pollutant list;
(4) pollution source sewage treatment facility water inlet water pollutant inventory
(5) pollution source sewage treatment facility water outlet water pollutant inventory
(6) discharge pollutants under improper industrial and mineral inventory
Quality standard of water environment and every profession and trade emission standard:
(1) U.S. EPA drinking water standard pollutant inventory
(2) Chinese water environment quality standard pollutant inventory (GB3838)
(3) life in China sanitary standard for drinking water pollutant inventory (GB5749)
In screening process, the determination of large list also needs with reference to U.S. EPA excellent pollution control dye name list 129 kinds and 68 kinds, middle national best pollution control dye thing blacklist etc.
(1) U.S. EPA excellent control name list
In U.S. EPA water environment, the list of 129 kinds of priority pollutants is in table 1:
129 kinds of priority pollutant lists in table 1 U.S. EPA water environment
(2) national best control name list in
Zhou Wenmin, Fu Deqian etc. are according to excellent control pollutant screening principle, set about from the investigating of the origins of industrial pollution and environmental monitoring, summarize about 100,000 data, and from national toxic chemical register base, retrieve the initial list of 2347 kinds of pollutants, finishing screen selects 68 kinds as control polluted articles lists all in water, in shown in table 2.2:
68 kinds of priority pollutant lists in table 2 water environment in China
Except these two large lists, also with reference to the chemical toxicity effect record of professional safety and health research institute of the U.S. (NISOH), (RTECS) reference such as data, hazardous chemical archives, Chemicals Database, utilizes the domestic and international priority acccess control of Gong the reference of aforementioned collection and the toxic chemical list of management to be selected in.
Gather according to above list and investigation of pollution sources and experimental data and arrange result and set up priority pollutants catalogue storehouse.
2 selected stages
According to the priority pollutants catalogue storehouse that the stage of roughly selecting sets up, comprehensive scoring method is adopted to carry out the screening of priority pollutants, qualitative-quantitative-datumization score-system screens roughly selecting list and sorts, sort according to each pollutant score, obtain the priority pollutants of each pollution source.
Set up points-scoring system, select to expose gesture, toxicity gesture, contact gesture and risk gesture four broad aspect, totally 13 parameters are as Score index, and these 13 parameters are respectively: solubleness, volatile grade, bioaccumulation, biodegradability, general toxicity, mutagenicity, teratogenesis, carcinogenicity in COD contribution margin, environment recall rate, concentrations, the percent be discharged in environment, production or use amount, water.
(1) standards of grading
Score value is higher shows that harm potentiality are larger, mark according to fixed standard, large multiparameter can formulate quantitative criterion, data that should not be quantitative take qualitative-Quantification Methods to carry out Standardized quantitative, provide suitable score value by pollutant character by analogical pattern during data lacuna, weighted stacking draws the total score value of pollutant.
(2) score value is determined:
Basic label follows following principle: the COD contribution margin > environment recall rate > concentrations > percent > be discharged in environment produces or solubleness > volatile grade > bioaccumulation > biodegradability > general toxicity > mutagenicity > teratogenesis > carcinogenicity in use amount > water
Concrete Score index and tax divide standard as follows:
(1) COD contribution margin is composed and is divided
By calculating theoretical oxygen demand (ThOD), with reference to the COD having material
crthe modes such as the stability of (acid potassium dichromate oxidation mensuration) oxygenation efficiency and organic contaminant calculate COD contribution margin, and oxygenation efficiency is maximum with 100% metering, for general organism, with empirical formula C
ah
bo
cn
dp
es
frepresent, its oxidation reaction is expressed from the next:
The i.e. organic compound C of 1mol
ah
bo
cn
dp
es
fto consume in the oxidation reaction
mole oxygen, be called theoretical oxygen demand (ThOD) by the COD value that this method calculates, result of calculation is as shown in table 3, and standards of grading are COD
crcontribution margin, COD
crcontribution margin be calculated as follows shown in formula.
COD
crcontribution margin (mg/L)=ThOD(g/g) × oxygenation efficiency (%) × concentrations (mg/L) ... ..
Potassium dichromate chemical oxygen demand (COD) oxygenation efficiency hierarchical table is as shown in table 3, COD
crcontribution margin to compose point standard as shown in table 4.
Table 3 potassium dichromate chemical oxygen demand (COD) oxygenation efficiency hierarchical table
Table 4COD
crcontribution margin compose submeter
Score value |
0 |
1 |
2 |
3 |
4 |
5 |
CODCr contribution margin (mg/L) |
0 |
0-50 |
50-100 |
100-200 |
200-300 |
>300 |
(2) environment recall rate is composed and is divided
Environment recall rate according to a little position all do not detect, stoste detects, sewage treatment facility import detects, sewage treatment facility outlet detects, sewage treatment facility import, outlet all detect (stoste import, stoste outlet), sewage treatment facility import, outlet, stoste all detect a point level Four tax point, as shown in table 5.
Table 5 environment recall rate composes submeter
(3) concentrations is composed and is divided
Carrying out tax according to the concentrations of pollutant divides as shown in table 6.
Table 6 concentrations composes submeter
(4) Environment release degree is composed and is divided
Be discharged into percent in environment with the difference of use-pattern and storage for score basis, in order to estimate entered environment number, point level Four is composed point, in table 7.
Table 7 Environment release degree composes submeter
(5) use amount is composed and is divided
Raw and auxiliary material storage and use, reaction intermediate, product use and storage capacity divides Pyatyi tax point, as shown in table 8.
Table 8 use amount composes submeter
Score value |
0 |
1 |
2 |
3 |
4 |
5 |
Standard (t/a) |
<1 |
1-10 |
10-100 |
100-1000 |
1000-10000 |
>10000 |
(6) biodegradability is composed and is divided
Usual biodegradability biological conversion and degradation coefficient (Kb) represent, biological conversion and degradation coefficient (Kb): biological conversion refers to the catalytic conversion process of biology enzyme to compound, the biological possibility transformed depends on stability and the toxicity of compound, existence and environmental factor etc. through acclimated microorganism (comprise pH value, temperature, the amount of dissolved oxygen DO and available nitrogen), biodegradable complexity is commonly referred to biodegradability, ratio that can be biochemical is through being commonly used to the important indicator of the toxic organic wastewater of expression biochemical process process, biochemical process is a longer process.The second order reaction rate constant of bioconversion rate, is decided by the concentration of compound and the amount of microorganism.
Biological conversion refers to the catalytic conversion process of biology enzyme to compound, the biological possibility transformed depends on stability and the toxicity of compound, through the existence and environmental factor etc. (comprising pH value, temperature, the amount of dissolved oxygen DO and available nitrogen) of acclimated microorganism.Biodegradable complexity is commonly referred to biodegradability, and ratio that can be biochemical is through being commonly used to the important indicator of the toxic organic wastewater of expression biochemical process process, and biochemical process is a longer process.The second order reaction rate constant of bioconversion rate, is decided by the concentration of compound and the amount of microorganism.
Biodegradability parameter data is complete, according to decompositions, countless certificate, not to decompose or very difficult decomposition three grades is composed and divided, and suitably to be composed point countless by pollutant analogical pattern according to pollutant.It is as shown in table 9 that biodegradability composes submeter.
Table 9 biodegradability composes submeter
Score value |
1 |
2 |
3 |
Standard |
Decompose |
Countless certificate |
Do not decompose or be difficult to decompose |
(7) bioaccumulation is composed and is divided
Bioaccumulation generally adopts bio-concentration factor (BCF) to evaluate, and for not having the pollutant of data to adopt compound apportioning cost analogy determination score value in n-octyl alcohol and water, point three grades of taxes divide as shown in table 10.
BCF is the concentration of compound in biological tissue's (dry weight) and the ratio being dissolved in the concentration in water.Also can think biological to the absorption rate of compound and the ratio of Organism compound purification rate, bio-concentration factor is the important indicator describing chemical substance accumulation tendency in vivo.As the data according to IRPTC, living in PCB content is fish in 1 μ g/L water, and the coefficient of concentration after 28 days is 37000 times of content in water body, then puts back to not containing in the clean water of PCB, and within 84 days, later purifying rate is 61%.Hydrobiont to the absorption of chemical substance and summation, has come often by the distribution between water and fat in water body.
K
oWorganic compound at the ratio of water and N-octanol biphase equilibrium concentration.Find according to research, octanol has the distribution of face matter very similar to organism at soil to organic distribution, so when there being the distribution ratio K of compound in pungent alcohol and water
oWafter, just successfully can calculate K
oC.Usually, the solubleness of organism in water often can be reflected by their compatibilities to nonpolar organic phase.Lipophilic organism has very high partition factor in octanol-water system, and the concentration in organic phase can reach 10 of concentration in aqueous phase
1~ 10
6doubly.Such as common environmental contaminants PAH, PCB
swith phthalic acid ester etc.Partition factor in octanol-water system is a dimensionless number.K
oWvalue describes a kind of organic compound in water and sediment, one that distributes between organic matter or between hydrobiont fat very useful index.The numerical value of partition factor is larger, and organism solubleness in organic phase is also larger, and the solubleness namely in water is less.
Table 10 bioaccumulation composes submeter
(8) solubleness and volatile grade are composed and are divided
To chemical substance, particularly in the environmental monitoring of poisonous chemical and environmental effect research process, their solubleness in water may be affect chemicals in various environmental element, as one of migration in air, water body, hydrobiont and sediment (substrate), most important properties of transforming.Major part mineral compound is ionic state in water, therefore its solubleness is all larger, and many organism are nonionic state, and the solubleness in water is then smaller.The dissolubility of nonionic compound, depends primarily on their polarity, and compound that is nonpolar or low pole is soluble in nonpolar or weak polar solvent, otherwise strong polar compound is soluble in polar solvent, and water is one of intensive polar solvent.So the non-polar compounds such as phenixin dissolve very few in water, arene compounds belongs to low pole, solubleness in water is also little, along with increase (as PAH) substituent in aromatic hydrocarbon ring, their solubleness in water is more and more less, the alcohol of contrary strong polarity, the solvent degree of compound in water of organic acid etc. and band OH, SH, NH, group is then quite large.
The vapor pressure of compound have expressed this compound from the extent of migration Environmental Water in opposite directions air, and generally speaking, have high vapor pressure, the compound of low solubility and high activity coefficient the most easily volatilizees, and the speed of volatilization is also decided by wind, current and temperature sometimes.General low-molecular-weight compound such as alkane, mononuclear aromatics and some organic nitrogen compounds have very high vapor pressure and very low water-soluble, and some data are also with enjoying sharp constant H
crepresent the volatility (unit of account Torr/mol) of compound.H
crepresent that the relative equilibrium concentrations of compound in air and water, the ratio of vapor pressure and people's compound solubleness in water, represents the volatility of this compound at standard temperature and pressure.
In water, solubleness and volatile grade parameter reference have chemical handbook and obtain, solubleness divide soluble in water, be slightly soluble in water and indissoluble or water insolublely compose 3,2,1 points respectively, concrete point standard of composing is in table 11; Volatile grade point volatility, half volatile and difficult volatility compose 1,2,3 point respectively, and concrete point standard of composing is in table 12.
Table 11 solubleness composes submeter
Score value |
1 |
2 |
3 |
Standard (mg/L) |
Indissoluble or water insoluble |
Be slightly soluble in water |
Soluble in water |
According to the definition boiling point of the World Health Organization (WHO) at the compound of 50 DEG C-250 DEG C, under room temperature, saturated vapor pressure is more than 133.32Pa, is present in the type organic in air at normal temperatures in vapour form.By the difference of its chemical constitution, eight classes can be further divided into: alkanes, aromatic hydrocarbons, alkene class, halohydrocarbon, ester class, aldehydes, ketone and other.The principal ingredient of VOC has: hydro carbons, halogenated hydrocarbons, oxygen hydrocarbon and nitrogen hydrocarbon, and it comprises: benzene homologues, organic chloride, freon series, organic ketone, amine, alcohol, ether, ester, acid and petroleum hydrocarbon compound etc.In general air, organic compound can be divided into four classes according to boiling point difference:
1, boiling point be less than 0 DEG C ~ 50 DEG C for volatile organic compound (VVOC)
2, that boiling point 50 DEG C ~ 240 DEG C is volatile organic matter (VOC)
According to the definition boiling point of the World Health Organization (WHO) at the compound of 50 DEG C-250 DEG C, under room temperature, saturated vapor pressure is more than 133.32Pa, is present in the type organic in air at normal temperatures in vapour form.By the difference of its chemical constitution, eight classes can be further divided into: alkanes, aromatic hydrocarbons, alkene class, halohydrocarbon, ester class, aldehydes, ketone and other.The principal ingredient of VOC has: hydro carbons, halogenated hydrocarbons, oxygen hydrocarbon and nitrogen hydrocarbon, and it comprises: benzene homologues, organic chloride, freon series, organic ketone, amine, alcohol, ether, ester, acid and petroleum hydrocarbon compound etc.
3, that boiling point 380 DEG C is semi-volatile organic compounds (SVOC)
4, that boiling point more than 380 DEG C is particulate organic matter (POM)
Table 12 volatile grade composes submeter
(9) general toxicity is composed and is divided
General toxicity is divided into chronic toxicity and acute toxicity, introduces half lethal dose LD
50(mg/kg), MLC (median lethal concertration) LC
50(mg/m
3), minimum toxic action dosimetry parameter TDL
0(mg/kg), TLC
0(mg/m
3) chronic toxicity and acute toxicity are evaluated, divide Pyatyi to compose and divide, carry out general toxicity tax according to the toxicity grading standard of World Health Organization's recommendation and divide as shown in table 13.Select from " chemical toxicity pandect ".
Table 13 general toxicity composes submeter
(10) specific toxicity is composed and is divided
Specific toxicity and carcinogenic, teratogenesis, mutagenic effect divide level Four to compose point, as shown in table 14,15,16 with reference to U.S.'s Institute for Occupational Health poisonous effect record.
Table 14 carcinogenicity composes submeter
Standard |
Non-carcinogenesis |
Tumour is caused by RTECS standard |
By RTECS standard, carcinogenic or people doubts carcinogenic |
Table 15 teratogenesis composes submeter
Score value |
0 |
1 |
2 |
Standard |
Without teratogenesis |
There is genotoxicity |
Animal subject teratogenesis or mankind's teratogenesis |
Submeter composed by table 16 mutagenicity
Set up the selected list of priority pollutants
Carry out to chemicals listed in the large list of each enterprise taxs according to above-mentioned tax point principle to divide, totally 13 parameters are respectively: solubleness, volatile grade, bioaccumulation, biodegradability, general toxicity, mutagenicity, teratogenesis, carcinogenicity in COD contribution margin, environment recall rate, concentrations, the percent be discharged in environment, production or use amount, water.The sequence of composing point result is according to the needs of screening according to normalized or sequence of directly suing for peace, or be weighted summation according to concrete demand, the compound obtaining each enterprise sorts, and finally obtains the priority pollutants of each enterprise.
The review stage
The expert group that review is made up of art authority at different levels carries out comprehensively comprehensive examination to each selected priority pollutants, expert can correct its irrationality in screening process and the shortage of data according to data and technical experience, what the error etc. of quantification process caused falsely drops, make preferred list more accurately, more reasonable.
The review stage is to the examination of large list before and the examination of scoring process, object is to find unsuitable place in screening process, remove some and should not appear at material in the selection result, and set up emergent priority pollutants list with reference to information such as enterprise's raw and auxiliary material, production technology production run, emergency trouble shooting measures.
Embodiment 2
Pesticide producing industry and enterprise priority pollutants inventory
According to priority pollutants screening process in embodiment 1, first the large list of priority pollutants of this enterprise is set up, then compose point principle according to screening and tax point is carried out to the chemical substance of this enterprise, metal and organism are composed point principle according to difference and are carried out, compose after dividing and each screening factor normalization sequence is obtained green despot's chemical substance ranking results, sequence material is before examination enterprise's priority pollutants, and appraisal result sees attached list 17.
Table 17 marking and queuing result
The product paraquat that this enterprise produces is chloro pesticide, the raw materials such as chlorine, pyridine, chloromethanes, methyl alcohol, sodium cyanide are used in production run, the experimentally organic and metal analysis data result of the routine of room to this institute of enterprise water sampling, in conjunction with basic conditions such as its production technology, raw material auxiliary material, sewage disposal devices, organism in this enterprise and metallic data are marked according to the index listed by excellent control pollutant screening technique, and sort according to the normalized result of each index, the priority pollutants list obtained, shown in table 18.
Table 18 pesticide producing enterprise priority pollutants list
Sequence number |
Chinese |
Molecular formula |
Normalizing sorts |
1 |
Toluene |
C7H8 |
5.80 |
2 |
3-methylphenol |
C8H10O |
5.60 |
4 |
A-phenyl benzil alcohol |
C13H12O |
5.50 |
5 |
Hexichol methoxyacetic acid |
C15H14O3 |
5.43 |
6 |
The bromo-3-methylphenol of 4- |
C7H7OBr |
4.90 |
7 |
2,2'-dipyridine |
C10H8N2 |
4.53 |
8 |
Methyl isobutyl ketone |
C6H12O |
4.33 |
9 |
Methyl Stearate |
C19H38O2 |
4.20 |
10 |
The chloro-phenol of 3,4,5-tri- |
C6H3Cl3O |
7.37 |
11 |
Phenol |
C6H60 |
6.87 |
12 |
N-acetyl group-2,5-dimethoxy-4 's-methyl |
C14H21NO3 |
6.60 |
13 |
The bromo-acetophenone of 2- |
C8H7Br |
6.57 |
14 |
Benzene |
C6H6 |
6.57 |
15 |
Tetrahydrofuran |
C4H8O |
6.13 |
16 |
2,3-difluorobenzonitrile |
C7H3F2N |
6.03 |
17 |
Acetic acid |
C2H4O2 |
5.93 |
18 |
DMA |
C8H11N |
5.70 |
20 |
The bromo-5-methylphenol of 2- |
C7H7OBr |
5.67 |
21 |
3,5-lutidines |
C7H9N |
5.67 |
22 |
3,4,5-trichloroaniline |
C6H4Cl3N |
5.60 |
23 |
3-ethyl-phenol |
C8H10O |
5.57 |
24 |
3,4-xylenol |
C8H10O |
5.37 |
25 |
2-amino-1-propyl alcohol |
C3H9ON |
5.33 |
26 |
4-methylphenol |
C7H8O |
5.27 |
27 |
Arsenic |
|
|
28 |
Zinc |
|
|
29 |
Selenium |
|
|
30 |
Molybdenum |
|
|
31 |
Total cyanide |
|
|
Pesticide screening test priority pollutants mainly comprises following classification:
1. phenolic compound: comprise phenol, monomethyl substituted phenol, dimethyl substituted phenol, halo phenols;
2. pyridine compounds and their: pyridine, dipyridine, methyl substituted pyridine
3. alcohol compound: comprise phenmethylol, amino replacement alcohols
4. prussiate (inorganic cyanide and organic cyanide): CN
-, cyanobenzene
5. aminated compounds: phenyl amines, amide-type
6. ketone compounds: methyl isobutyl ketone, Benzophenone
7. heavy metal class: manganese, nickel, thallium, arsenic, zinc, selenium, molybdenum
What its Poisoning was higher is phenols, prussiate, heavy metal class material, and the main and raw material of priority pollutants, auxiliary material (comprising solvent, catalyzer etc.), side reaction product are closely related.
Contrast with EPA list and middle national best control name list: have with the material matched in U.S. EPA list: benzene, toluene,
Phenol, prussiate, arsenic, selenium, nickel, zinc, thallium.
The material matched with Chinese 68 kinds of priority pollutants has: benzene, toluene, phenol, 3-methylphenol, prussiate, arsenic, selenium, nickel, zinc, thallium.
The screening of emergent priority pollutants is also organic based on the routine of laboratory to this institute of enterprise water sampling and metal analysis data result, and in conjunction with green despot's product, production technology, raw material auxiliary material, sewage disposal device, environmental risk assessment, the basic conditions such as pesticide industry emission standard, organism in green despot and metallic data are marked according to the index listed by excellent control pollutant screening technique emergent in chapter 2, and sort according to the normalized result of each index, obtain the priority pollutants list of green despot, mainly comprise following classification: phenolic compound, pyridine compounds and their, alcohol compound, prussiate, aminated compounds, ketone compounds, heavy metal class etc.
There is harm and mainly contain two kinds of situations in this enterprise, one is fire, explosion hazard, because the material that uses in production run and product have inflammability; Two to be that supplementary material and product relate to hazardous chemical more, and its main hazard shows as toxic hazard effect.In production, major toxicity material has chlorine, toluene, methyl alcohol, DMF, ammonia, pyridine, benzoyl peroxide etc., and wherein chlorine is main harm thing, is secondly toluene and pyridine.
Table 19 agricultural chemicals enterprise meets an urgent need priority pollutants list
Sequence |
Chinese |
Molecular formula |
Normalization is arranged |
1 |
Toluene |
C7H8 |
5.80 |
2 |
3-methylphenol |
C8H10O |
5.60 |
4 |
A-phenyl benzil alcohol |
C13H12O |
5.50 |
5 |
Hexichol methoxyacetic acid |
C15H14O3 |
5.43 |
6 |
The bromo-3-methylphenol of 4- |
C7H7OBr |
4.90 |
7 |
2,2'-dipyridine |
C10H8N2 |
4.53 |
8 |
Methyl isobutyl ketone |
C6H12O |
4.33 |
9 |
Methyl Stearate |
C19H38O2 |
4.20 |
10 |
The chloro-phenol of 3,4,5-tri- |
C6H3Cl3O |
7.37 |
11 |
Phenol |
C6H60 |
6.87 |
12 |
N-acetyl group-2,5-dimethoxy-4 's-methyl |
C14H21NO3S |
6.60 |
13 |
The bromo-acetophenone of 2- |
C8H7Br |
6.57 |
14 |
Benzene |
C6H6 |
6.57 |
15 |
Tetrahydrofuran |
C4H8O |
6.13 |
16 |
2,3-difluorobenzonitrile |
C7H3F2N |
6.03 |
17 |
Acetic acid |
C2H4O2 |
5.93 |
18 |
DMA |
C8H11N |
5.70 |
20 |
The bromo-5-methylphenol of 2- |
C7H7OBr |
5.67 |
21 |
3,5-lutidines |
C7H9N |
5.67 |
22 |
3,4,5-trichloroaniline |
C6H4Cl3N |
5.60 |
23 |
3-ethyl-phenol |
C8H10O |
5.57 |
24 |
Manganese |
|
|
25 |
Nickel |
|
|
26 |
Thallium |
|
|
27 |
Arsenic |
|
|
28 |
Zinc |
|
|
29 |
Selenium |
|
|
30 |
Molybdenum |
|
|
31 |
Total cyanide |
|
|
Embodiment 3
The screening study of oil refining industry priority pollutants
The pollutant that the stock and adjunct of this enterprise may enter water body is petroleum-type, benzene homologues, phenol, aldoketones, ethers, alkanes, olefines, multiring aromatic hydrocarbon etc.
Production technology mainly comprises electro-desalting, atmospheric and vacuum distillation, catalytic cracking, delayed coking etc.
Sewage treatment process adopts the treatment process such as oil removal, all quality regulate, two-stage pressure dissolved air floatation, biomembrance process anaerobic treatment and two-stage activated sludge process plug-flow aeration aerobic treatment (A/O2), rear flocculation, biological activated carbon.
Oil refining industry represents enterprise's marking and queuing result
Adopt the electro-desalting of this enterprise in summation sequence and normalization sortord, delayed coking, atmospheric and vacuum distillation, the organic contaminant of the technique waste water mensuration such as catalytic cracking can carry out screening and sequencing, as shown in table 20 and table 21, contrast two tables can find out, adopt two kinds of different modes sequences, technique waste water characteristic contamination does not have notable difference mainly to comprise phenol, benzene homologues, naphthalene series substance, aldoketones, alkanes.
Table 20 oil refining enterprise stoste inventory (summation sequence)
Sample |
Chinese |
Molecular formula |
Summation sequence |
Delayed coking |
2-methylphenol |
C8H10O |
21 |
Electro-desalting |
Benzene |
C6H6 |
21 |
Atmospheric and vacuum distillation |
Benzene |
C6H6 |
21 |
Atmospheric and vacuum distillation |
Phenol |
C6H6O |
21 |
Delayed coking |
Phenol |
C6H6O |
20.5 |
Catalytic cracking |
Phenol |
C6H6O |
20.5 |
Delayed coking |
4-methylphenol |
C7H8O |
20 |
Electro-desalting |
2-methyl-trans decahydronaphthalene |
C11H20 |
20 |
Electro-desalting |
P-xylene |
C8H10 |
20 |
Catalytic cracking |
3-methylphenol |
C8H10O |
20 |
Atmospheric and vacuum distillation |
3-methylphenol |
C7H8O |
20 |
Atmospheric and vacuum distillation |
P-xylene |
C8H10 |
20 |
Electro-desalting |
4-methylphenol |
C8H10O |
19.5 |
Delayed coking |
P-xylene |
C8H10 |
19 |
Electro-desalting |
Naphthalene |
C10H8 |
19 |
Electro-desalting |
Isosorbide-5-Nitrae-dimethyl-1,2,3,4-tetrahydro-naphthalene |
C12H16 |
19 |
Electro-desalting |
Phenol |
C6H6O |
19 |
Catalytic cracking |
Benzene |
C6H6 |
19 |
Catalytic cracking |
2-methylphenol |
C7H8O |
19 |
Catalytic cracking |
4-methylphenol |
C7H8O |
19 |
Catalytic cracking |
2-aminotoluene |
C7H9N |
19 |
Atmospheric and vacuum distillation |
2-espeleton |
C5H12 |
18.5 |
Electro-desalting |
1-methylnaphthalene |
C11H10 |
18 |
Electro-desalting |
16-dimethylnaphthalene |
C13H14 |
18 |
Catalytic cracking |
3-methylaniline |
C7H9N |
18 |
Atmospheric and vacuum distillation |
Dibutyl phthalate |
C16H22O4 |
18 |
Atmospheric and vacuum distillation |
Acetone |
C3H6O |
18 |
Atmospheric and vacuum distillation |
N-butyl alcohol |
C4H10O |
18 |
Atmospheric and vacuum distillation |
2-methylphenol |
C7H8O |
18 |
Atmospheric and vacuum distillation |
4-methylphenol |
C7H8O |
18 |
Atmospheric and vacuum distillation |
Ethylbenzene |
C8H10 |
18 |
Electro-desalting |
14-dimethylnaphthalene |
C12H12 |
17.5 |
Electro-desalting |
2,3-dihydro-1,1,3-trimethyl-1H-indenes |
C12H16 |
17.5 |
Electro-desalting |
2-methylphenol |
C8H10O |
17.5 |
Catalytic cracking |
P-xylene |
C8H10 |
17.5 |
Delayed coking |
Acetone |
C3H6O |
17 |
Electro-desalting |
2,6-dimethylnaphthalene |
C12H12 |
17 |
Electro-desalting |
Toluene |
C7H8 |
17 |
Catalytic cracking |
Aniline |
C6H7N |
17 |
Atmospheric and vacuum distillation |
Toluene |
C7H8 |
17 |
Atmospheric and vacuum distillation |
2,5-xylenol |
C8H10O |
17 |
Atmospheric and vacuum distillation |
2,3-dimethyl-3-hexanol |
C8H18O |
17 |
Electro-desalting |
2-methylnaphthalene |
C11H10 |
16.5 |
Catalytic cracking |
Acetone |
C3H6O |
16.5 |
Atmospheric and vacuum distillation |
Naphthalene |
C10H8 |
16.5 |
Delayed coking |
2,3-xylenol |
C8H10O |
16 |
Electro-desalting |
Pentane |
C5H12 |
16 |
Electro-desalting |
Cyclohexane |
C6H12 |
16 |
Electro-desalting |
Methyl cyclopentane |
C6H12 |
16 |
Electro-desalting |
2-methylpentane |
C6H14 |
16 |
Electro-desalting |
Hexane |
C6H14 |
16 |
Electro-desalting |
2,4-dimethyl pentane |
C7H16 |
16 |
Electro-desalting |
O-xylene |
C8H10 |
16 |
Electro-desalting |
Anti-form-1,2-dimethyl cyclohexane |
C8H16 |
16 |
Electro-desalting |
Cis-1,2-dimethylcyclopentane |
C8H16 |
16 |
Electro-desalting |
Cis-1,3-dimethyl cyclohexane |
C8H16 |
16 |
Electro-desalting |
1,2,3-trimethylbenzene |
C9H12 |
16 |
Electro-desalting |
1,3,5-trimethylbenzene |
C9H12 |
16 |
Electro-desalting |
2-methylheptane |
C9H16 |
16 |
Electro-desalting |
2-methyl hexane |
C9H16 |
16 |
Electro-desalting |
3-methylheptane |
C9H16 |
16 |
Electro-desalting |
1,1,3-trimethyl-cyclohexane |
C9H18 |
16 |
Electro-desalting |
1,2,3-trimethyl cyclopentane |
C9H18 |
16 |
Electro-desalting |
1-methyl-3-(1-Methylethyl) cyclopentane |
C9H18 |
16 |
Electro-desalting |
Anti-form-1,1,3,4 methyl cyclopentanes |
C9H18 |
16 |
Electro-desalting |
2,6-dimethyl heptane |
C9H20 |
16 |
Electro-desalting |
3-ethyl-2,2 dimethyl pentane |
C9H20 |
16 |
Atmospheric and vacuum distillation |
1-methylnaphthalene |
C11H10 |
16 |
Atmospheric and vacuum distillation |
2 pentanone |
C5H10O |
16 |
Atmospheric and vacuum distillation |
Enanthic acid |
C7H14O2 |
16 |
Atmospheric and vacuum distillation |
2,4-xylenol |
C8H10O |
16 |
Delayed coking |
Toluene |
C7H8 |
15.5 |
Catalytic cracking |
2-butanone |
C4H8O |
15.5 |
Catalytic cracking |
Toluene |
C7H8 |
15.5 |
Atmospheric and vacuum distillation |
Cyclohexane |
C5H10 |
15.5 |
Atmospheric and vacuum distillation |
Pentane |
C5H12 |
15.5 |
Atmospheric and vacuum distillation |
Methyl isobutyl ketone |
C6H12O |
15.5 |
Atmospheric and vacuum distillation |
1-Ethyl-2-Methyl benzene |
C9H12 |
15.5 |
Delayed coking |
Butane |
C4H10 |
15 |
Delayed coking |
(Z)-2-butylene |
C4H8 |
15 |
Delayed coking |
3,4-xylenol |
C8H10O |
15 |
Electro-desalting |
1-(3,4-3,5-dimethylphenyl)-ethyl ketone |
C10H11O |
15 |
Electro-desalting |
Decahydro-2-methylnaphthalene |
C10H18 |
15 |
Electro-desalting |
Methylcyclohexane |
C6H12 |
15 |
Electro-desalting |
Nonane |
C9H20 |
15 |
Catalytic cracking |
Methyl isobutyl ketone |
C6H12O |
15 |
Atmospheric and vacuum distillation |
Butane |
C4H10 |
15 |
Atmospheric and vacuum distillation |
Methyl cyclopentane |
C6H12 |
15 |
Atmospheric and vacuum distillation |
Cumene |
C9H12 |
15 |
Table 21 oil refining enterprise stoste inventory (normalization sequence)
Sample |
Chinese |
Molecular formula |
Normalization is sorted |
Electro-desalting |
Benzene |
C6H6 |
7.03 |
Atmospheric and vacuum distillation |
Benzene |
C6H6 |
7.03 |
Catalytic cracking |
Benzene |
C6H6 |
6.63 |
Atmospheric and vacuum distillation |
Phenol |
C6H6O |
6.43 |
Electro-desalting |
P-xylene |
C8H10 |
6.37 |
Atmospheric and vacuum distillation |
P-xylene |
C8H10 |
6.37 |
Electro-desalting |
2-methyl-trans decahydronaphthalene |
C11H20 |
6.37 |
Delayed coking |
Phenol |
C6H6O |
6.33 |
Catalytic cracking |
Phenol |
C6H6O |
6.33 |
Delayed coking |
2-methylphenol |
C8H10O |
6.27 |
Electro-desalting |
4-methylphenol |
C7H8O |
6.27 |
Electro-desalting |
Isosorbide-5-Nitrae dimethyl 1,2,3,4-tetrahydro-naphthalene |
C12H16 |
6.17 |
Delayed coking |
P-xylene |
C8H10 |
6.17 |
Electro-desalting |
Naphthalene |
C10H8 |
6.03 |
Electro-desalting |
Phenol |
C6H6O |
6.03 |
Electro-desalting |
1,6-dimethylnaphthalene |
C13H14 |
5.97 |
Delayed coking |
4-methylphenol |
C7H8O |
5.93 |
Catalytic cracking |
3-methylphenol |
C7H8O |
5.93 |
Atmospheric and vacuum distillation |
3-methylphenol |
C7H8O |
5.93 |
Catalytic cracking |
P-xylene |
C8H10 |
5.87 |
Catalytic cracking |
4-methylphenol |
C7H8O |
5.87 |
Catalytic cracking |
2-aminotoluene |
C7H9N |
5.87 |
Electro-desalting |
Isosorbide-5-Nitrae-dimethylnaphthalene |
C12H12 |
5.87 |
Electro-desalting |
1-methylnaphthalene |
C11H10 |
5.83 |
Electro-desalting |
2,6-dimethylnaphthalene |
C12H12 |
5.77 |
Catalytic cracking |
2-methylphenol |
C7H8O |
5.73 |
Electro-desalting |
2,3-dihydro-1,1,3-trimethyl-1H-indenes |
C12H16 |
5.73 |
Catalytic cracking |
3-methylaniline |
C7H9N |
5.53 |
Atmospheric and vacuum distillation |
2-methylphenol |
C7H8O |
5.53 |
Atmospheric and vacuum distillation |
4-methylphenol |
C7H8O |
5.53 |
Electro-desalting |
2-methylnaphthalene |
C11H10 |
5.53 |
Atmospheric and vacuum distillation |
Naphthalene |
C10H8 |
5.53 |
Atmospheric and vacuum distillation |
Acetone |
C3H6O |
5.50 |
Electro-desalting |
2-methylphenol |
C8H10O |
5.43 |
Atmospheric and vacuum distillation |
1-methylnaphthalene |
C11H10 |
5.43 |
Atmospheric and vacuum distillation |
Ethylbenzene |
C8H10 |
5.37 |
Atmospheric and vacuum distillation |
Dibutyl phthalate |
C16H22O4 |
5.33 |
Atmospheric and vacuum distillation |
2-espeleton |
C5H12 |
5.30 |
Delayed coking |
Acetone |
C3H6O |
5.30 |
Electro-desalting |
Toluene |
C7H8 |
5.20 |
Atmospheric and vacuum distillation |
Toluene |
C7H8 |
5.20 |
Catalytic cracking |
Acetone |
C3H6O |
5.20 |
Atmospheric and vacuum distillation |
N-butyl alcohol |
C4H10O |
5.07 |
Catalytic cracking |
Aniline |
C6H7N |
5.03 |
Delayed coking |
(Z)-2-butylene |
C4H8 |
4.93 |
Delayed coking |
Toluene |
C7H8 |
4.90 |
Catalytic cracking |
Toluene |
C7H8 |
4.90 |
Atmospheric and vacuum distillation |
2,3-dimethyl-3-hexanol |
C8H18O |
4.87 |
Atmospheric and vacuum distillation |
Cyclohexane |
C5H10 |
4.73 |
Catalytic cracking |
1,3-butadiene |
C4H6 |
4.73 |
Electro-desalting |
O-xylene |
C8H10 |
4.70 |
Atmospheric and vacuum distillation |
2 pentanone |
C5H10O |
4.67 |
Atmospheric and vacuum distillation |
2,5-xylenol |
C8H10O |
4.60 |
Delayed coking |
Butane |
C4H10 |
4.60 |
Atmospheric and vacuum distillation |
Butane |
C4H10 |
4.60 |
Catalytic cracking |
2-butanone |
C4H8O |
4.57 |
Atmospheric and vacuum distillation |
Pentane |
C5H12 |
4.57 |
Atmospheric and vacuum distillation |
Methyl isobutyl ketone |
C6H12O |
4.57 |
Electro-desalting |
Pentane |
C5H12 |
4.53 |
Electro-desalting |
Cyclohexane |
C6H12 |
4.53 |
Electro-desalting |
Methyl cyclopentane |
C6H12 |
4.53 |
Electro-desalting |
2-methylpentane |
C6H14 |
4.53 |
Electro-desalting |
Hexane |
C6H14 |
4.53 |
Electro-desalting |
2,4-dimethyl pentane |
C7H16 |
4.53 |
Electro-desalting |
Anti-form-1,2-dimethyl cyclohexane |
C8H16 |
4.53 |
Electro-desalting |
Cis-1,2-dimethylcyclopentane |
C8H16 |
4.53 |
Electro-desalting |
Cis-1,3-dimethyl cyclohexane |
C8H16 |
4.53 |
Electro-desalting |
1,2,3-trimethylbenzene |
C9H12 |
4.53 |
Electro-desalting |
1,3,5-trimethylbenzene |
C9H12 |
4.53 |
Electro-desalting |
2-methylheptane |
C9H16 |
4.53 |
Electro-desalting |
2-methyl hexane |
C9H16 |
4.53 |
Electro-desalting |
3-methylheptane |
C9H16 |
4.53 |
Electro-desalting |
1,1,3-trimethyl-cyclohexane |
C9H18 |
4.53 |
Electro-desalting |
1,2,3-trimethyl cyclopentane |
C9H18 |
4.53 |
Electro-desalting |
1-methyl-3-(1-Methylethyl) cyclopentane |
C9H18 |
4.53 |
Electro-desalting |
Anti-form-1,1,3,4-tetramethyl-ring pentane |
C9H18 |
4.53 |
Electro-desalting |
2,6-dimethyl heptane |
C9H20 |
4.53 |
Electro-desalting |
3-ethyl-2,2 dimethyl pentane |
C9H20 |
4.53 |
Atmospheric and vacuum distillation |
Enanthic acid |
C7H14O2 |
4.53 |
Electro-desalting |
Butane |
C4H10 |
4.50 |
Atmospheric and vacuum distillation |
Cumene |
C9H12 |
4.47 |
Atmospheric and vacuum distillation |
1-Ethyl-2-Methyl benzene |
C9H12 |
4.43 |
Atmospheric and vacuum distillation |
1-chloro-octane |
C8H17Cl |
4.37 |
Catalytic cracking |
Methyl isobutyl ketone |
C6H12O |
4.33 |
Atmospheric and vacuum distillation |
Methyl cyclopentane |
C6H12 |
4.33 |
Oil refining enterprise's nominal situation priority pollutants inventory:
Consider the production technology of this enterprise, sewage treatment process, the using and consume and sewage treatment facility is imported and exported and the monitoring of technique waste water of raw and auxiliary material, determine that the said firm's nominal situation production priority pollutants is shown in table 22, mainly comprise following classification: phenol, benzene homologues, naphthalene series substance, phenyl amines, aldoketones, phthalate and heavy metal.Phenol mainly comprises: phenol, monomethyl phenol, xylenol; Benzene homologues mainly comprises: benzene, toluene, o-xylene, m-xylene, P-xylene, trimethyl substituted benzene; Naphthalene series substance mainly comprises: naphthalene, dimethylnaphthalene methylnaphthalene, methylnaphthalene, monomethyl naphthalene; Phenyl amines mainly comprises: aniline, monomethyl aniline (MMA); Phthalate mainly comprises: diisobutyl phthalate, diisooctyl phthalate; Heavy metal mainly comprises: selenium, antimony, barium, mercury, nickel; Other also contain: methyl tert-butyl ether, acetone.
Table 22 oil refining enterprise priority pollutants list
In conjunction with this technical basis such as enterprise's environmental emergency scheme and hazardous chemical Major Hazard Installations Identifying, analyze the environmental risk accident obtaining this enterprise potential and mainly contain the following aspects: the accidents such as the race of fire explosion, oil product is emitted, oil-gas pipeline leakage, dangerous chemical leakage (comprising acidulous water, liquid ammonia storage tank, auxiliary material storage tank etc.), ruinous earthquake, Rainfall Disaster, to the potential pollutant that water body exists are: pH value, petroleum-type, benzene homologues, phenol, aldoketones, ethers, alkanes, olefines, multiring aromatic hydrocarbon etc.It is shown in table 23 that combined process Wastewater Determination result and accident dump obtain this enterprise's damage priority pollutants of meeting an urgent need, and mainly comprises following classification: phenol, benzene homologues, naphthalene series substance, phenyl amines, aldoketones, phthalate and heavy metal.Phenol mainly comprises: phenol, monomethyl phenol, xylenol; Benzene homologues mainly comprises: benzene, toluene, o-xylene, m-xylene, P-xylene, trimethyl substituted benzene; Naphthalene series substance mainly comprises: naphthalene, monomethyl naphthalene, dimethylnaphthalene; Phenyl amines mainly comprises: aniline, 3-methylaniline; Aldoketones mainly comprises: acetone, (2-thiophene phenol sulfenyl) acetone, 2-espeleton; Phthalate mainly comprises: dibutyl phthalate, diisooctyl phthalate; Heavy metal mainly comprises: selenium, antimony, barium, mercury, nickel, vanadium, manganese, total chromium, zinc, arsenic, molybdenum.
What its Poisoning was higher is phenols, palycyclic aromatic, prussiate, heavy metal class material, and the main and raw material of priority pollutants, auxiliary material (comprising solvent, catalyzer etc.), side reaction product are closely related.
Contrast with EPA list and middle national best control name list: have with the material matched in U.S. EPA list: benzene, toluene, P-xylene, o-xylene, phenol, aniline, prussiate, n-butyl phthalate, selenium, antimony, mercury, nickel, zinc, arsenic.The material matched with Chinese 68 kinds of priority pollutants has: benzene, toluene, P-xylene, o-xylene, aniline, phenol, 3-methylphenol, prussiate, Dibutyl phthalate, dioctyl phthalate, selenium, antimony, mercury, nickel, zinc, arsenic.
Meet an urgent need priority pollutants list in table 23 oil refining enterprise
Sequence number |
Sample |
Chinese |
Molecular formula |
Normalization is sorted |
1 |
Refinery import |
Phenol |
C6H6O |
7.43 |
2 |
Electro-desalting |
Benzene |
C6H6 |
7.03 |
3 |
Refinery import |
2-methylphenol |
C7H8O |
6.60 |
4 |
Refinery import |
3-methylphenol |
C7H8O |
6.60 |
5 |
Refinery import |
4-methylphenol |
C7H8O |
6.40 |
6 |
Refinery import |
1-methylnaphthalene |
C11H10 |
6.40 |
7 |
Electro-desalting |
P-xylene |
C8H10 |
6.37 |
8 |
Electro-desalting |
2-methyl-trans decahydronaphthalene |
C11H20 |
6.37 |
9 |
Refinery import |
Naphthalene |
C10H8 |
6.30 |
10 |
Refinery import |
2-methylnaphthalene |
C11H10 |
6.30 |
11 |
Refinery import |
3-methylaniline |
C7H9N |
6.20 |
12 |
Electro-desalting |
Isosorbide-5-Nitrae-dimethyl-1,2,3,4-tetrahydro-naphthalene |
C12H16 |
6.17 |
13 |
Refinery exports |
(2-thiophene phenol sulfenyl) acetone |
C7H8OS2 |
6.13 |
14 |
Refinery import |
2,7-dimethylnaphthalene |
C12H12 |
5.97 |
15 |
Electro-desalting |
1,6-dimethylnaphthalene |
C13H14 |
5.97 |
16 |
Refinery import |
Toluene |
C7H8 |
5.87 |
17 |
Electro-desalting |
Isosorbide-5-Nitrae-dimethylnaphthalene |
C12H12 |
5.87 |
18 |
Catalytic cracking |
2-aminotoluene |
C7H9N |
5.87 |
19 |
Refinery import |
3-methylnaphthalene |
C11H10 |
5.77 |
20 |
Refinery import |
1,7-dimethylnaphthalene |
C12H12 |
5.77 |
21 |
Refinery import |
2,6-dimethylnaphthalene |
C12H12 |
5.77 |
22 |
Electro-desalting |
2,3-dihydro-1,1,3-trimethyl-1H-indenes |
C12H16 |
5.73 |
23 |
Catalytic cracking |
3-methylaniline |
C7H9N |
5.53 |
24 |
Atmospheric and vacuum distillation |
Acetone |
C3H6O |
5.50 |
26 |
Refinery exports |
Diisooctyl phthalate |
C24H38O4 |
5.43 |
27 |
Refinery import |
O-xylene |
C8H10 |
5.37 |
28 |
Atmospheric and vacuum distillation |
Ethylbenzene |
C8H10 |
5.37 |
29 |
Atmospheric and vacuum distillation |
Dibutyl phthalate |
C16H22O4 |
5.33 |
30 |
Atmospheric and vacuum distillation |
2-espeleton |
C5H12 |
5.30 |
31 |
Catalytic cracking |
Acetone |
C3H6O |
5.20 |
32 |
Atmospheric and vacuum distillation |
N-butyl alcohol |
C4H10O |
5.07 |
33 |
Refinery import |
M-xylene |
C8H10 |
5.07 |
34 |
Catalytic cracking |
Aniline |
C6H7N |
5.03 |
35 |
Refinery import |
1,2,4-trimethylbenzene |
C9H12 |
5.00 |
37 |
|
Selenium |
|
|
38 |
|
Antimony |
|
|
39 |
|
Barium |
|
|
40 |
|
Mercury |
|
|
41 |
|
Nickel |
|
|
42 |
|
Vanadium |
|
|
43 |
|
Manganese |
|
|
44 |
|
Total chromium |
|
|
45 |
|
Zinc |
|
|
46 |
|
Arsenic |
|
|
47 |
|
Molybdenum |
|
|
48 |
|
CN |
|
|
Embodiment 4
The screening study of metallurgy industry priority pollutants
With certain iron and steel enterprise for representative, the main raw and auxiliary material of this iron and steel enterprise: iron ore (or fine ore), coal (or coke), water, steel scrap, lime stone etc.
Composite wastewater treatment plant adopts the method for physical treatment (highly dense and V filter)+advanced treating (ultrafiltration and counter-infiltration) to dispose of sewage.
This iron and steel enterprise is mainly engaged in the secondary product such as production and sales metallurgical coke and coal tar, crude benzol, ammonium sulfate, coke-oven gas and firmly wants the scope of business: the secondary products such as production and sales mechanical coke and coal tar, crude benzol, ammonium sulfate, coke-oven gas.
Production technology adopts the side of making firm by ramming of domestic advanced person to fill coke oven, environment-friendly type production equipment and chemical products reclaimer.Coke oven is made up of 263 hole carbonization chambers, and carbonization chamber is high 4.3 meters, produce coke and meet national secondary metallurgical standard completely.The synchronous auxiliary construction of coke oven is pulverized, coaling, coke pushing, sieve transport burnt dust arrester, gas purification recovery, wastewater biochemical treatment facility.
Wastewater treatment adopts advanced Jiang Hua patent pre-service+A2/O+TNC system in combination technique, Treatment of Wastewater in Coking 140m per hour
3, ton water running expense 3.5-7.5 yuan, day, discharge capacity was up to 3360m
3/ d.Coking chemical waste water water outlet after this PROCESS FOR TREATMENT reaches " steel and iron industry pollution discharge standard " primary standard, and processed waste water fully recovering is in quenching moisturizing.
Danger in fuel, auxiliary material and chemicals involved in production run, objectionable impurities a lot, mainly contain SO
2, CO, benzene, NOx, H2S, CmHn, coal dust, Jiao Chen, NH3, B [a] P, sulfuric acid, NaOH etc., above-mentioned material all has the hazard profiles such as inflammable, explosive, poisonous, harmful, corrosion.Project construction facility mainly comprises the facilities such as coke oven, gas purification, storage, and its main hazard characteristic is fire explosion and leakage accident.To the potential pollutant that water body exists be: pH value, petroleum-type, benzene homologues, phenol, prussiate, heavy metal, multiring aromatic hydrocarbon etc.
Metallurgy industry priority pollutants inventory
In conjunction with technical basis such as metallurgy industry environmental emergency scheme and hazardous chemical Major Hazard Installations Identifying, analyze the environmental risk accident obtaining this enterprise potential and mainly contain the following aspects: the accidents such as the race of fire explosion, oil product is emitted, oil-gas pipeline leakage, dangerous chemical leakage (comprising acidulous water, liquid ammonia storage tank, auxiliary material storage tank etc.), ruinous earthquake, Rainfall Disaster, to the potential pollutant that water body exists are: pH value, petroleum-type, benzene homologues, phenol, prussiate, heavy metal, multiring aromatic hydrocarbon etc.
This enterprise's nominal situation priority pollutants is shown in table 24, mainly contains following classification: phenol, benzene homologues, alcohol acids, heterocyclic and heavy metal.Phenol mainly comprises: phenol, many groups fortified phenol; Benzene homologues mainly comprises: toluene, P-xylene; Alcohol acids: polysubstituted amylalcohol, hexanol, enanthol, enanthic acid etc.; Heterocyclic comprises: DOX, 1 hydrogen-
Benzotriazole; Heavy metal mainly comprises: selenium, mercury, thallium, nickel, manganese, molybdenum.
Table 24 smelting enterprise priority pollutants list
Smelting enterprise's nominal situation priority pollutants is as shown in Table 25, mainly contains following classification: phenol, naphthalene series substance, alkanes, alcohol acids, heterocyclic and heavy metal.Phenol mainly comprises: phenol, monomethyl phenol; Naphthalene series substance mainly comprises: naphthalene, naphthols, naphthylamines; Alkanes mainly comprises: 1,2,4,5-tetra-sulphur cyclohexane, 1,2,4,5,7,8-six thia cyclononane, trithio cyclopentane, 1,1,2,2-tetrachloroethane; Alcohol acids mainly comprises: 2,2-dimethyl succinic acid, 2,4-dimethyl-3-hexanols, quinoline-8-carbonic acid, phenyl decyl alcohol; Heterocyclic mainly comprises: 2-ethyl-4-methyl isophthalic acid, 3-dioxolanes, 1-methyl-isoquinolin, 1,2,3-trimethyl-1H-indoles, quinoline, indoles; Heavy metal mainly comprises: mercury, nickel, thallium, selenium; Other also have benzo [a] anthracene, vinyl cyanide.
Table 25 smelting enterprise coking priority pollutants list
Sequence number |
Chinese |
Molecular formula |
Normalization is sorted |
|
|
|
|
1 |
2,2-dimethyl succinic acid |
C6H10O4 |
4.52 |
2 |
2,4-dimethyl-3-hexanol |
C8H18O |
4.38 |
4 |
Quinoline-8-carbonic acid |
C10H7NO2 |
4.18 |
5 |
2-ethyl-4-methyl isophthalic acid, 3-dioxolanes |
C6H12O2 |
4.18 |
6 |
Phenyl decyl alcohol |
C16H26O |
4.05 |
7 |
1-methyl-isoquinolin |
C10H9N |
3.98 |
8 |
1,2,3-trimethyl-1H-indoles |
C11H13O |
3.98 |
9 |
1,2,4,5-tetra-sulphur cyclohexane |
C2H4S4 |
3.95 |
10 |
1,2,4,5,7,8-six thia cyclononane |
C3H6S6 |
3.95 |
11 |
Trithio cyclopentane |
C2H4S3 |
3.05 |
12 |
Phenol |
C6H6O |
7.85 |
13 |
2-naphthylamines |
C10H9N |
7.18 |
14 |
1-naphthols |
C10H8O |
6.92 |
15 |
Naphthalidine |
C10H9N |
6.88 |
16 |
Beta naphthal |
C10H8O |
6.82 |
17 |
2-methylphenol |
C7H8O |
6.68 |
18 |
4-methylphenol |
C7H8O |
6.68 |
20 |
Vinyl cyanide |
C3H3N |
6.18 |
21 |
1,1,2,2-tetrachloroethane |
C2H4Cl4 |
5.68 |
22 |
Aniline |
C6H7N |
5.68 |
23 |
Naphthalene |
C10H8 |
5.47 |
24 |
Benzo [a] anthracene |
C18H12 |
5.40 |
25 |
Quinoline |
C9H7N |
4.95 |
26 |
Indoles |
C8H7N |
4.92 |
27 |
Mercury |
|
|
28 |
Nickel |
|
|
29 |
Thallium |
|
|
30 |
Selenium |
|
|
31 |
Total cyanide |
|
|
The emergent priority pollutants of this smelting enterprise is shown in table 26, mainly contains following classification: phenol, benzene homologues, aldoketones, alcohol acids, heterocyclic, phthalate and heavy metal.Phenol mainly comprises: phenol, monomethyl phenol, many groups fortified phenol, 2,4,6-iodophenisic acids; Benzene homologues mainly comprises: toluene, P-xylene; Aldoketones comprises: isoquinoline-1-ketone; Alcohol acids: polysubstituted amylalcohol, hexanol, enanthol, enanthic acid etc.; Heterocyclic comprises: DOX, 4-methyl isophthalic acid hydrogen-benzotriazole; Phthalate mainly comprises: dibutyl phthalate, dioctyl phthalate; Heavy metal mainly comprises: selenium, mercury, thallium, nickel, manganese, molybdenum, zinc.
Table 26 smelting enterprise meets an urgent need priority pollutants list
Sequence number |
Chinese |
Molecular formula |
Normalization is sorted |
1 |
3-methylphenol |
C7H8O |
5.80 |
2 |
4-methyl isophthalic acid-hydrogen-benzotriazole |
C7H7N3 |
4.73 |
4 |
Diphenyl methane |
C13H12 |
3.23 |
5 |
2,4,6-iodophenisic acid |
C6H3OI3 |
4.23 |
6 |
Dibutyl phthalate |
C16H22O4 |
3.77 |
7 |
Dioctyl phthalate |
C24H38O4 |
3.77 |
8 |
Isoquinoline-1-ketone |
C9H7NO |
3.57 |
9 |
2-TBP |
C10H14O |
4.83 |
10 |
4-TBP |
C10H14O |
4.83 |
11 |
Phenol |
C6H6O |
6.27 |
12 |
P-xylene |
C8H10 |
5.43 |
13 |
DOX |
C3H6O2 |
5.20 |
14 |
2,4-DTBP |
C14H22O |
5.03 |
15 |
Toluene |
C7H8 |
4.93 |
16 |
2,3-dimethyl-1-butanol |
C6H14O |
4.90 |
17 |
2-tert-butyl-4-methyl-Phenol |
C11H16O |
4.83 |
18 |
2,3,4-trimethyl-3-amylalcohol |
C8H18O |
4.80 |
19 |
3,3-dimethyl enanthic acid |
C9H18O2 |
4.80 |
20 |
2,4-dimethyl-3-hexanol |
C8H18O |
4.80 |
21 |
1 hydrogen-benzotriazole |
C6H5N |
4.73 |
22 |
2,6-di-t-butyl-4-ethyl-phenol |
C16H26O |
4.47 |
23 |
2,6-DI-tert-butylphenol compounds |
C14H22O |
4.37 |
24 |
4-(1,1-dimethyl propyl) phenol |
C11H16O |
4.37 |
25 |
Selenium |
|
|
26 |
Mercury |
|
|
27 |
Thallium |
|
|
28 |
Nickel |
|
|
29 |
Manganese |
|
|
30 |
Zinc |
|
|
31 |
Total cyanide |
|
|
Embodiment 4
The screening study of fertilizer industry priority pollutants
Fertilizer industry represents enterprise's basic condition
This enterprise has the series of products such as synthetic ammonia, methyl alcohol, nitric acid, carbon dioxide, carbon ammonium, the pollutant that stock and adjunct may enter water body be V2O5, soda ash, catalyst for methanol, copper, acetic acid, hydrochloric acid, propylene carbonate solvent, caustic soda, CO2 desulfurizing agent, CO2 desulfurizing agent, platinum guaze catalyzer, magnesium nitrate, nitric acid tail gas process catalyzer, lubrication wet goods.
Production technology: the operations such as ammonia alcohol process units comprises gas making, semiwater gas desulphurizing, conversion, desulfuration of shift gas, carbon third decarburization, flashed vapour reclaim (former carbonization), fine de-sulfur, connection alcohol, copper are washed, ammonia synthesis, refined methanol.First phase nitric acid engineering comprises dust technology device, red fuming nitric acid (RFNA) device two parts.Second phase nitric acid engineering comprises dust technology device, red fuming nitric acid (RFNA) device two parts.Also have food-grade carbon-dioxide project, aniline etc.
Sewage treatment process: adopt short distance nitration A/SBR new technology, sewage, after collection conduits is collected, is removed through grid and is floated
The impurity such as thing, suspension, gravity flow enters homogeneous regulating reservoir.By lift pump, sewage is sent into Prepositive denitrification A pond, waste water mixes with SBR pond phegma through plug-flow machine plug-flow, in the effect of anaerobe, utilizes the COD in water to carry out denitrification, by the NO in the phegma of SBR pond
2 -and N0
3 -major part removing.If C/N is too small in water, methyl alcohol need be added.The water outlet in A pond flows into SBR pond, at aerobic stage by COD, the NH in water
4the pollutants such as-N decompose, are converted into H
2o, CO
2, NO
2 -, N0
3 -deng material; At anaerobic stages by NO
2 -, N0
3 -be converted into N
2, significantly remove COD and NH in waste water
4-N.SBR water outlet enters Buffer Pool by water filter, send biofilter through lift pump by sewage, and biological bacteria is retained by biofilter material, and during backwash, backwash water sends regulating reservoir back to.Biofilter standard water discharge is arranged outward.
Fertilizer industry priority pollutants inventory
In conjunction with technical basis such as fertilizer industry environmental emergency scheme and hazardous chemical Major Hazard Installations Identifying, analyze the environmental risk accident obtaining chemical fertilizer potential and mainly contain the following aspects: the accident such as fire explosion, dangerous chemical leakage (comprising ammonia, methyl alcohol, monomethyl amine, dimethylamine, trimethylamine, DMF storage tank, auxiliary material storage tank etc.), ruinous earthquake, Rainfall Disaster, to the potential pollutant that water body exists be: pH value, ammonia nitrogen, benzene homologues, phenol, phenyl amines, nitrobenzene, prussiate etc.
Chemical fertilizer nominal situation priority pollutants is shown in table 27, mainly contains following classification: phenol, dimethylbenzene, alcohol ketone, prussiate and heavy metal.Phenol mainly comprises: phenol, monomethyl phenol, xylenol and pseudocuminol; Alcohol ketone mainly comprises: 2-butanone, a-phenyl benzil alcohol, 3-methyl-cyclopentanone, methyl isobutyl ketone; Heavy metal mainly comprises: mercury.
Table 27 fertilizer enterprises priority pollutants list
Sequence number |
Chinese |
Normalization is sorted |
1 |
Phenol |
7.20 |
2 |
2-methylphenol |
5.83 |
4 |
Toluene |
5.70 |
5 |
Dimethylbenzene |
5.60 |
6 |
4-methylphenol |
5.50 |
7 |
3-methylphenol |
5.30 |
8 |
2,3-xylenol |
5.23 |
9 |
Benzene acetonitrile |
5.20 |
10 |
2,4-xylenol |
5.13 |
11 |
2,6-bis-bromo-4-methylphenol |
5.10 |
12 |
3,4-xylenol |
5.03 |
13 |
2-butanone |
4.97 |
14 |
A-phenyl benzil alcohol |
4.70 |
15 |
3-methyl-cyclopentanone |
4.67 |
16 |
Methyl isobutyl ketone |
4.63 |
17 |
Benzothiazole |
4.60 |
18 |
3-hexanol |
4.53 |
20 |
2,5-xylenol |
4.50 |
21 |
3-ethyl-phenol |
4.40 |
22 |
2,4-DTBP |
4.40 |
23 |
2 pentanone |
4.33 |
24 |
2,3,5-TEP |
|
25 |
Mercury |
|
26 |
Total cyanide |
|
What fertilizer industry priority pollutants Poisoning was higher is the materials such as benzene, phenol, phenyl amines, nitrobenzene heavy metal, and the main and raw material of priority pollutants, auxiliary material, side reaction product, sewage treatment process are closely related.Emergent priority pollutants be in raw material produce have outside the Pass, also closely related with sudden pollution accident.
Contrast with EPA list and middle national best control name list: the material coincide with U.S. EPA list has: benzene, aniline, phenol, 3-methylphenol, prussiate, nitrobenzene, arsenic, mercury, selenium, nickel, antimony; The material coincide with Chinese 68 kinds of priority pollutants has: benzene, aniline, phenol, 3-methylphenol, prussiate, nitrobenzene, arsenic, mercury, selenium, nickel, antimony.
According to technical basis such as fertilizer industry environmental risk assessment and Sudden Environmental Pollution Accident emergency disposal prediction scheme, hazardous chemical Major Hazard Installations Identifying, analyze the environmental risk accident obtaining life chemical industry potential and mainly contain the following aspects: fire, explosion hazard; Toxic hazard; Mechanical fault; Collision accident; Human factor; External factor etc.To the potential pollutant that water body exists be: benzene homologues, nitrobenzene, phenyl amines, sulfuric acid, nitric acid etc.
Fertilizer enterprises priority pollutants list of meeting an urgent need is shown in table 28, and comparative analysis can be found out, fertilizer industry is met an urgent need, and priority pollutants is leaked in raw material, production technology is closely related.Fertilizer industry priority pollutants is benzene homologues, phenol, nitrobenzene, phenyl amines, prussiate, arsenic, mercury, selenium, nickel, antimony etc.
Table 28 fertilizer enterprises is met an urgent need priority pollutants list
Sequence number |
Chinese |
Normalization is sorted |
1 |
Phenol |
7.20 |
2 |
2-methylphenol |
5.83 |
4 |
Toluene |
5.70 |
5 |
Dimethylbenzene |
5.60 |
6 |
4-methylphenol |
5.50 |
7 |
3-methylphenol |
5.30 |
8 |
2,3-xylenol |
5.23 |
9 |
Benzene acetonitrile |
5.20 |
10 |
2,4-xylenol |
5.13 |
11 |
2,6-bis-bromo-4-methylphenol |
5.10 |
12 |
3,4-xylenol |
5.03 |
13 |
2-butanone |
4.97 |
14 |
A-phenyl benzil alcohol |
4.70 |
15 |
3-methyl-cyclopentanone |
4.67 |
16 |
Methyl isobutyl ketone |
4.63 |
17 |
Benzothiazole |
4.60 |
18 |
3-hexanol |
4.53 |
20 |
2,5-xylenol |
4.50 |
21 |
3-ethyl-phenol |
4.40 |
22 |
2,4-DTBP |
4.40 |
23 |
2 pentanone |
4.33 |
24 |
2,3,5-TEP |
|
25 |
Mercury |
|
26 |
Total cyanide |
|
What fertilizer industry priority pollutants Poisoning was higher is the materials such as benzene, phenol, phenyl amines, nitrobenzene heavy metal, and the main and raw material of priority pollutants, auxiliary material, side reaction product, sewage treatment process are closely related.Emergent priority pollutants be in raw material produce have outside the Pass, also closely related with sudden pollution accident.
Contrast with EPA list and middle national best control name list: the material coincide with U.S. EPA list has: benzene, aniline, phenol, 3-methylphenol, prussiate, nitrobenzene, arsenic, mercury, selenium, nickel, antimony; The material coincide with Chinese 68 kinds of priority pollutants has: benzene, aniline, phenol, 3-methylphenol, prussiate, nitrobenzene, arsenic, mercury, selenium, nickel, antimony.