Purpose: To analyze the odor components in food waste treatment process. Method: Cold trap enrichment-GC/MS technology was used to determine the component. Result: The detection results showed that the levels of odorant concentrations from the main processing units were ranked in the order of: temperature sterilization device > oil-water separator > anaerobic fermenter > separation equipment > unloading area. Oxygenated organic compounds were the main components. Conclusion: Ethanol, hydrogen sulfide, dimethyl disulfide, ammonia, limonene were characteristic pollutants in the unloading areas and separation equipment; ethanol, methyl mercaptan, hydrogen sulfide, dimethyl disulfide, limonene were characteristic pollutants in the temperature sterilization device and oil-water separator; ethanol, hydrogen sulfide, dimethyl disulfide, p-diethylbenzene, limonene were characteristic pollutants in the anaerobic fermenter.
With rapid progress of living standard and city restaurant industry, the amount of daily food waste generates over 20 thousand tons in China [
We found the odor source mainly came from the discharge, high temperature sterilization, sorting, oil-water separation, anaerobic fermentation units. Samples were collected and analyzed for each unit. Sampling time: April 11th - 13th, 2014; sampling site temperature: 11.4˚C - 14.5˚C; pressure: 101.1 - 101.4 kPa; wind speed: 0.5 - 1.1 m/s; humidity: 33.2% - 46.7%.
GC9800 gas chromatography mass spectrometry (CHN); Markes Unity solid adsorption-thermal desorption (GBR); Entech canister sampling-cold trap concentration system (USA); Wosaite DR59C-NH3 portable ammonia detector (CHN).
The odor concentration analysis method of reference was “Air quality-Determination of odor-Triangle odor bag method” (GB/T14675-93). The analysis method for VOCs referenced USA EPATO-15.
By quantitative analysis of samples, the food waste disposal device emissions were detected with 10 kinds of alkane, 4 olefin, 17 aromatic, 9 halogenated, 4 organic compounds containing oxygen, 3 sulphur compounds and 2 other compounds (ammonia and naphthalene). Furthermore, 41 kinds of pollutants were detected in unloading area, the concentration level was 5.37 mg/m3; 43 kinds of pollutants were detected in high temperature sterilization device, the concentration level was 15.62 mg/m3; 42 kinds of pollutants were detected in sorting device, the concentration level was 8.31 mg/m3; 41 kinds of pollutants were detected in sorting device, the concentration level was 8.26 mg/m3; 43 kinds of pollutants in oil water separation device, the concentration level was 13.16 mg/m3; 43 kinds of pollutants in anaerobic fermentation device, the concentration level was 13.21 mg/m3.
In order to highlight the characteristics of pollution sources emissions, the odor concentration of pollutant emissions for each unit was normalized. By analyzing, we found that ethanol, ammonia, limonene were the main substance discharged from each unit of the food waste disposal system, its significant content covered the features of other pollutants component in the spectrum, so the materials mentioned above were not included in each unit component spectrum. Compared with other regions, unloading area was more easily leaking. The composition and content distribution of unloading area (concentration ≥ 0.10%) were shown in
As we can see, pollutants in the exhaust gas of each unit were basically the same. The material with the most significant normalized concentration was ethanol, followed by ammonia, limonene, dichloromethane and toluene, ethyl acetate, propane, carbon disulfide, isobutene etc. In addition, ammonia, dimethyl disulfide, hydrogen sulfide, carbon disulfide, methyl mercaptan were all the controlled materials of emission standards for odor pollutants in China [
The test sample odor concentration (dimensionless) showed the odor concentration in discharge area was 722; the high temperature sterilization device was 4130; the sorting device was 3067; the oil-water separation device was 2311; the anaerobic fermentation device was 2306. The stench was results of various substances. Usually, the main pollutants were the malodorous substance with higher diluted multiples, but we can’t completely decided that odor substance with the highest diluted multiples made the biggest contribution [
Odor Source | Top 5 Substances Concentration | Top 5 Threshold Dilution | ||
---|---|---|---|---|
Substance Name | Concentration (mg/m3) | Substance Name | Threshold Dilution (dimensionless) | |
Unloading Area | ethanol | 4.66 | hydrogen sulfide | 48 |
ammonia | 0.19 | dimethyl disulfide | 13 | |
limonene | 0.10 | ethanol | 8 | |
dichloromethane | 0.05 | limonene | 2 | |
toluene | 0.03 | ammonia | 1 | |
High Temperature Sterilization | ethanol | 14.83 | methyl mercaptan | 69 |
ammonia | 0.44 | hydrogen sulfide | 57 | |
limonene | 0.17 | ethanol | 27 | |
toluene | 0.05 | dimethyl disulfide | 4 | |
ethyl acetate | 0.03 | limonene | 4 | |
Sorting Device | ammonia | 7.67 | methyl mercaptan | 37 |
ethanol | 0.44 | ethanol | 16 | |
dichloromethane | 0.11 | dimethyl disulfide | 13 | |
limonene | 0.07 | limonene | 3 | |
carbon disulfide | 0.04 | ammonia | 2 | |
Oil-water Separation Device | ethanol | 12.52 | methyl mercaptan | 68 |
ammonia | 0.18 | hydrogen sulfide | 53 | |
limonene | 0.13 | ethanol | 22 | |
ethyl acetate | 0.05 | dimethyl disulfide | 12 | |
toluene | 0.03 | limonene | 4 | |
Anaerobic Fermentation Device | ethanol | 12.49 | hydrogen sulfide | 54 |
ammonia | 0.37 | ethanol | 26 | |
limonene | 0.10 | dimethyl disulfide | 14 | |
dichloromethane | 0.04 | ammonia | 6 | |
toluene | 0.03 | limonene | 3 |
Food waste has characteristic with high water content (60% - 80%), high organic matter proportion (more than 95% dry matter), high salt content, less harmful substances and rich nutrition, which is very valuable for recycling [
1) Through the analysis of spectral components, ethanol emissions was the most significant during food waste disposal process, monitoring data show that ethanol normalized concentration was more than 85% of each unit, the reason may due to the alcohol residue and recycled products during anaerobic process. Ingredients of other pollutants were basically the same; the normalized concentration of ammonia, limonene, and dichloromethane was relatively high.
2) Each unit of food waste disposal facilities of anaerobic respectively detected 42 - 44 kinds of air pollutants, including alkane, olefin, benzeneseries, halogenated hydrocarbons, oxy-organics, sulfur compounds and other compounds, among which the concentration of oxy-organics was the highest.
Pollutant concentration level was in the order of: high temperature sterilization device > oil-water separation device > anaerobic fermentation device > sorting device > unloading zone.
3) Through the analysis of odor concentration, high temperature sterilization device, separating device, oil- water separator, anaerobic fermentation device were obviously higher than those in the discharge area, which were the main odor source of this kind of enterprises. The total concentration level of pollutants exhaust gas separation device was not high, but the odor concentrations were relatively high, which due to a certain amount of extremely low odor threshold concentration hydrogen sulfide.
4) Preliminary identification conclusion of typical pollutants. For the unloading area and sorting device, the typical pollutants were ethanol, hydrogen sulfide, dimethyl disulfide, ammonia, limonene. The typical pollutants in high temperature sterilization, oil-water separation device were ethanol, methyl mercaptan, hydrogen sulfide, dimethyl disulfide, limonene; In anaerobic fermentation device, the typical pollutants were ethanol, hydrogen sulfide, dimethyl disulfide, limonene.
This research was supported by Shandong Province Natural Science Fund Project (ZR2012HL08); Shandong Province Science and Technology Research Projects (2013GSF11828); 2013 Technology Project of Major Accident Prevention Key Technologies for Safe Production (LAJK2013-112); Jinan Science and Technology Development Project (20130244).
WeiQu,AihuaSong,YongleShan,RuiWang, (2015) Component Analysis of Odor Components in Food Waste Treatment. Journal of Environmental Protection,06,671-674. doi: 10.4236/jep.2015.67060