Introduction

In the past few decades, the large amounts of animal ma- nure and slurries have been produced by the animal breed- ing sector as well as the wet organic waste streams represent a constant pollution risk with a potential negative impact on the environmental, if not managed optimally. When untreated or poorly managed, animal manure be- comes a major source of air and water pollution. Nutrient leaching, mainly nitrogen, phosphorus and ammonia evap- oration and pathogen contamination are some of the major threats [1]. The animal production sector is responsible for 18% of the overall greenhouse gas emissions, measured in CO2 equivalent and for 37% of the anthropogenic methane, which has 23 times the global warming potential of CO2 [2]. Annually, approximately 400 million tons of wastes have been produced by Iran livestock industry (cattle and poultry) and agriculture sector. It means that it really needs an integrated waste management.

Anaerobic co-digestion of organic matters results in waste stabilization as well as in biogas production. This gas usually contains more than 50% methane, and there- fore it can be used as bio-fuel in power generation sys- tems to produce heat and energy [3]. Wastes have been effectively used as biogas materials by various studies [4]. The other Benefits of the anaerobic digestion of ani- mal manure are pathogen reduction through sanitation, improved fertilization efficiency, less nuisance from odors and flies and etc. [5]. Anaerobic digestion reduces the majority of pathogenic agents, if can be carried out under mesophilic or thermophilic conditions [6].

The anaerobic digestion of organic material is a com- plex process, involving a number of different degrad- ation steps. The microorganisms that participate in the process may be specific for each degradation step and thus could have different environmental requirements such as temperature, pH, moisture, carbon source, nitro- gen and C/N ratio. Many researchers have reported significant effects of temperature on the microbial com- munity, process kinetics and stability and methane yield. Lower temperatures during the process are known to decrease microbial growth, substrate utilization rates, and biogas production. Moreover, lower temperatures may also result in an exhaustion of cell energy, a leakage of intracellular substances or complete lysis. In contrast, high temperatures lower biogas yield due to the produc- tion of volatile gases such as ammonia which suppresses methanogenic activities [7].

Animal waste often has very high total ammonia nitrogen concentrations due to presence of ammonia as well as pro- tein and urea [8]. Nitrogen is an essential nutrient for an- aerobic organisms [9], consequently, the inhibitory effects of ammonia, as far as is known, influence mainly the phase of methanogenesis in anaerobic reactors [10], released from decomposition of organic ammonia. It has been suggested that poultry manure is best treated with other wastes be- cause of its high nitrogen content [11]. Crop residues rep- resent another fraction of agricultural waste. Substantial quantities of unused stalks, straws and bark are produced from a variety of crops, which could be used for energy generation, but they are poor substrate in term of nitrogen and phosphate. Therefore, co-digestion of animal manure and crop residues can supply a proper C/N ratio for micro- organisms. This ratio is the balance of food that a microbe requires in order to grow. The optimal C/N ratio is 20-30 and excess N can lead to ammonia inhibition of digestion [12]. The unbalanced nutrients are regarded as an import- ant factor limiting anaerobic digestion of organic wastes. For the improvement of nutrition and C/N ratios, co- digestion of organic mixtures is employed.

In spite of high production of poultry manure, anaerobic digestion of this kind of organic waste has not been stud- ied as much as cow and swine manure. Cow manure is a cellulose-rich component that high amount of cellulose and hemi- cellulose cause suitable C/N ratio and therefore it can be digested easily in anaerobic conditions. It is also a good fertilizer as it will not burn the plants. Inversely, poultry manure is an ammonia-rich component which cannot be used as a fertilizer because it will burn the plants as a result of high ammonia content. In order to obtain suitable C/N ratio, co-digestion of poultry manure has been done with hog manure, swine manure, fruit and vegetable wastes [13]. Co-digestion can utilize the nutri- ents and bacterial diversities in various wastes to optimize the digestion process. Co-digestion of poultry manure with wheat straw that has been done in this study may be considered as a new issue and the objective of the study is finding the optimum temperature and loading rate in a pilot-scale reactor that will be discussed fully below.

Material and methods

Waste characteristics

The poultry waste and straw were obtained from a local farm in Tehran and stored at 4°C. Poultry manure and straw were mixed together, straw with portion of 80% by weight and Poultry manure 20% by weight in order to supply a proper C/N ratio (C/N[asymptotically =]23). The waste mixture consist of 90% total solid (TS) and 80% of TS was Vola- tile Solid. The other characteristics of waste are presented in Table 1. Components of the obtained sam- ples were determined by the procedures described in the Standard Methods [14].

Experimental set-up

A cylindrical CSTR reactor with a working volume of 60 L (total digester volume 70 L) was operated at a 15d HRT for all runs. The reactor was fitted with a top plate, which supported the mixer, mixer motor and gas sam- pler. Sampling valves were located at positions corre- sponding to the top, middle and bottom layer of digester contents. The reactor had one outlet at the bottom for effluent removal. The contents of the reactor were mixed as controlled by a timer, which was activated for 30 min every hour. It was operated at 35°C and then was obtained at 30°C and 25°C.

Reactor operation

First, 40 L of anaerobic sludge from a dairy factory and 20 L water were transferred to the reactor. Daily feeding was commenced approximately 24 days after start-up. Raw waste characteristics over the study period are given in Table 1. The digestion operated at 25°C, 30°C and 35°C with organic loading rates of 1.0, 2.0, 2.5, 3.0, 3.5 and 4.0 kg VS/m3d. For preventing accumulation, because of daily feeding, 4 liters of content was removed every day. It was calculated according to HRT of 15 days. It is worth mentioning that gradual hydrolysis of cellulose caused the high amount of COD accumulation.

Analytical methods

The produced biogas was measured daily by water dis- placement method and its composition was measured by gas chromatograph. Total solids (TS), volatile solids (VS), pH and alkalinity were determined according to the APHA Standard Methods [14]. Total nitrogen (TN) was estimated by the Kjeldahl method [14].

Result

Effect of temperatures and feed loads on the methane yield

The influence of temperatures and feed loads on the methane yield is shown in Figure 1. Regardless of the temperature, increasing the feed load from 2.0 to 3.0 kg VS/m3d increased the methane yield and after that, a gradual increase in the OLR caused a decrease in the methane yield. According to the results, total gas production reached the highest amount at 35°C for a loading rate of 3.0 kgVS/m3d (0.12 m3CH4/kgVS) and methane yield increased (43% higher at 35°C rela- tive to 25°C) with a temperature increase from 25 to 35°C. At 35°C, ultimate methane yield of 0.061, 0.12 and 0.02 m3CH4/kg VS were obtained at 2.0, 3.0 and 4.0 kgVS/m3d, respectively.

Effect of temperatures and feed loads on biogas composition

One of the main objectives of this research was to deter- mine production and composition of biogas during anaer- obic process at different loading rates and temperatures. The biogas production at steady-state condition was found to be 44.8, 36 and 26 L/d at a load of 3.0 kg VS/m3dat35, 30 and 25°C, respectively. Further increase of the feeding rate up to 4.0 kg VS/m3dresultedindecreasesinbio- gas production rates. The variation of methane produc- tionisshowninFigure2.Themaximummethane contents (70.2%) were calculated at a load of 3.0 kg VS/m3d (35°C) and the minimum (30%) was at a load of 4.0 kg VS/m3d (25°C).

Effect of temperatures and feed loads on COD accumulation

Population of anaerobic microorganisms and their adap- tation to the new environmental conditions typically take a significant period of time to establish themselves to be fully effective. According to Figure 3, a small quan- tity of methane production at the first load allowed for accumulation of soluble COD up to 3010 mg/L at 2.5 kg VS/m3d and ascending rates of methane production were observed. After a gradual increase of OLR up to 3.0 kg VS/m3d, methane production increased up to 31.4 L/d and COD reached 3200 mg/L. VS removal was calculated 72% at this load but it decreased at other loads. In the next loads of 3.5 and 4.0 kg VS/m3d COD increased up to 3800 and 4900 mg/L, respectively (at pH= 7.5 and 7.1, free ammonia concentration 240 and 261 mg/L). The process appeared inhibited and/or overloaded by the accumulation of volatile fatty acids that lead methanogens to be inactive. The results at 30 and 35°C were similar.

Effect of temperatures and feed loads on pH

The pH variation at 35°C is shown in Figure 4. The pH stabilized between 6.8±0.1 and 7.8±0.1 in all runs. Hence the pH, which did not vary significantly among different loads, was in the optimum range for methanogens in all treatments. Total NH3-N within each load did not vary a lot, and ranged from 68 to 256 mg/L (Figure 4).

Discussion

Effect of temperatures and feed loads on the methane yield

The loading rate and temperature are obviously critical process parameters in anaerobic treatment. The influ- ence of temperature and feed loads on the methane yield have been shown in Figure 1. These findings are in agreement with the results of Alvarez et al. [15]. They reported that there was a linear relationship between methane yield and loading rate at lower loading rates. The maximum methane yield was observed at 35°C (0.12 m3CH4/kgVS) because of the suitable type and composition of substrate, microbial composition and temperature. At intermediate loading rates, methane yield was almost constant up to a certain loading at which it starts to decrease. This breakpoint indicates the beginning of biological stress and beyond this point, the methane production rate decreased sharply. At 30°C, the yield was 0.045, 0.096 and 0.0157 m3CH4/kgVS for loads of 2.0, 3.0 and 4.0 kg VS/m3d, respectively that was lower than the yields at 35°C. Callaghan et al. [11] have reported the methane yield of 0.23 m3/kgVS and 50% VS reduction by using a co-digestion system of fruit and vegetable waste (FVW) and Chicken manure with HRT of 21 days at 35°C. According to Salminen et al. [16], the potential methane yield of solid poultry slaughterhouse waste and HRT of 50-100 days at 31°C is high, from 0.52 to 0.55 m3/kg VS. The treatment of wastewaters containing high levels of TS or indigestion components, such as slaughterhouse wastewater or straw, will require a longer reaction period for complete degradation of particles, especially at lower temperatures. It is the most important reason of low methane yield in this case study compared with the others' results. Design parameters and related data are presented in Table 2.

Effect of temperatures and feed loads on biogas composition

Decreases in the methane content indicated hydraulic and organic overload and insufficient buffering capacity in the digester that they led to a reduction in the methanogenic activity. Chae et al. [17] reported that the biogas compos- ition differed according to digestion temperature. Methane contents in the biogas were 65.3%, 64.0% and 62.0% at 35°C, 30°C and 25°C, respectively.

Effect of temperatures and feed loads on COD accumulation

Decrease in the temperature had a negative effect on the metabolic rate of the microorganisms. For this rea- son, at 25°C COD increased sharply. Once 5100 mg/L, was reached, methane production decreased by 40% and VS removal dropped to 39%. In fact, the effect of temperature on organic removal rate did not seem to be uniform over the whole temperature spectrum. Chae et al. [17] reported that the digestion yield at a temperature of 25°C showed 82.6% of that at 35°C. These results were in agreement with previous results that showed an improvement in the biogas yields with increasing temperatures [18].

Effect of temperatures and feed loads on pH

The pH stabilized between 6.8±0.1 and 7.8±0.1 in all runs. Both total and free ammonia concentration varied a bit between stages. A wide range of inhibiting am- monia concentrations has been reported in the pa- pers the amount of ammonia in the digester may also affect the production of hydrogen and removal of volatile solids. Total biogas production was un- affected by small increases in ammonia nitrogen while higher increases reduced the biogas production by 50% of the original rate. In the fluidized-bed an- aerobic digester, the methane formation decreased at ammonium concentrations of greater than 6000 mg NH4-N/L. It was reported that methanogenic activity is decreased by 10% at ammonium concentrations of 1670-3720 mg NH4-N/L, while by 50% at 4090-5550 mg NH4-N/L, and completely zero at 5880-6000 mg NH4-N/L [19].

The free NH3±N concentrations calculated in this study were far below those reported as inhibitory be- cause of a) dilution of digester content with water and b) adjustment of feed C/N ratio. It should also be noted that both methanogenic and acidogenic microorganisms have their optimal pH. There is a considerable potential of biogas production from anaerobic digestion of poultry manure that offers several environmental, agricultural and socio-economic benefits throughout biogas produc- tion as a clean and renewable fuel. The process worked well with a loading of 3.0 kgVS/m3d VS removal amounted 72%. The temperature had an influence on the ultimate methane yield, as well as the methane con- tents. The highest temperature caused the most methane yield (0.12 m3/kg VS); however, the yield did not linearly increase with increasing temperature. More amount of methane yield may be achieved by extension of the hydraulic residence time because of the high levels of TS in waste.

Conclusion

The study clearly indicates that anaerobic digestion is one of the most effective biological processes to treat a wide variety of solid organic waste products. The prime advantages of this technology include (i) organic wastes with a low nutrient content can be degraded by co- digesting with different substrates in the anaerobic bio- reactors, and (ii) the process simultaneously leads to low cost production of biogas, which could be vital for meet- ing future energy-needs. However, different factors such as substrate and co-substrate composition and quality, environmental factors (temperature, pH, organic loading rate), and microbial dynamics contribute to the effi- ciency of the anaerobic digestion process, and must be optimized to achieve maximum benefit from this tech- nology in terms of both energy production and organic waste management. This technology has tremendous application in the future for sustainability of both envi- ronment and agriculture, with the production of energy as an extra benefit.

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

AB participated in the conception of the study, interpretation of data and in the given final approval of the version to be published; JSH supervised the study in all steps (acquisition, analysis, and interpretation of data); AR participated in the acquisition, analysis, and interpretation of data and helped to draft the manuscript. All authors read and approved the final manuscript.

Acknowledgment

The authors would like to thank the Department of Chemical Engineering, Sharif University of Technology, for their providing help in the labs.