HU226831B1 - Process for biological cleaning of separated water phase of liquid dung - Google Patents

Abstract

The subject of the invention is a procedure for cleaning of aqueous phase of liquid manure. The aqueous phase of manure is treated with a bacterial inoculating substance containing Bacillus megatherium, Bacillus subtilis, Pseudomonas putida, Pseudomonas fluorescens, Micrococcus roseus in germ number of 10<5> to 10<9> germs/ml. The inoculating substance in given case is applied onto a compost carrier and/or onto a carrier of ash of sunflower seeds shell and/or a carrier of chopped maize stems. The treatment is carried out at a temperature of 30 to 35 C°, under continuous aeration advantageously during time period of 10 to 20 days.

Description

The present invention relates to a process for the biological purification of a separated liquid manure liquid phase.

In practice, the utilization of slurry from livestock farms is a serious problem.

By slurry is meant an aqueous solution obtained by separation by separating the settled high solids slurry sludge phase from the lower solids aqueous phase.

The agricultural use of slurry, which is usually applied to soil, is severely limited by the fact that certain parameters of the treated slurry, such as its ammonium, nitrate, phosphate, sulphate and bacteriological contamination, do not allow direct agricultural utilization. .

In many cases, this disadvantage is present even in the case of slurry undergoing treatment.

The presence of Salmonella species in the slurry, especially pig manure, and Campylobacter, Eschericia, Yersinia species makes the direct application of slurry to the soil difficult from a hygienic point of view.

Liquid fertilizers contain high numbers of cellulose-degrading, nitrifying and nitrogen-binding microorganisms and therefore significant emissions of NH ₃ , CH ₄ and N ₂ O are expected during storage, handling and application of the slurry.

Many methods are known in the literature for reducing the solids, macro, micro-nutrient content and bacteriological contamination of slurry using mechanical and technical-technological equipment.

In the treatment of slurry, partial purification methods developed by combining mechanical and biological systems can achieve favorable results with respect to the physico-chemical and bacteriological parameters of the final product (Vermes L. Waste Management. Agricultural Publication, 1998, pp. 98-106).

In addition to the presence of harmful physical and chemical parameters, the bacteriological characteristics do not always allow the slurry to be utilized in agriculture.

Barótfi I. (2000): Environmental Technology. Agricultural Publisher, 457-461. p. After aerobic biological treatment in a reactor according to the method of the present invention, a slurry of a hygienic grade of good quality can be obtained.

H. Heionen-Tanski et al., Journal of Applied Microbiology, 2002, 85: p. According to Articles 277 to 281, Salmonella species can be effectively suppressed under aerobic conditions with continuous oxygen supply at temperatures below 40 ° C.

C. H. Burton and J. W. Journal of Agricultural Engineering Research, 1998, 69: p. In Articles 159 to 167, a significant reduction in organic matter in slurry can be achieved by using an intensive aeration period of nearly 20 days.

According to Hungarian Patent No. 205,336, pig slurry is mixed with a certain amount of keratinous waste and peat, which is matured into a compost, and is used as a soil improver.

Purification of pig slurry and municipal sewage is the subject of Hungarian Patent No. 210,317, according to which slurry is passed through a rheolite tuff filter, utilizing the very high cation adsorption and biogas gas adsorption capacity of rhyolite tuff.

Thus, a final product suitable for further use is obtained.

The disadvantages of the above procedures are that it is usually not possible to reduce the nitrogen and phosphorus content of the slurry to the required level in one step and at the same time to control the human and animal pathogens in the slurry.

The known aerobic processes are usually too lengthy and cannot, however, produce a finished product characterized by the desired quality parameters and suitable for agricultural purposes.

It is an object of the present invention to provide a method by which, in addition to reducing the organic matter, total nitrogen, total phosphorus, ammonium content of slurry, preferably pig slurry, human and animal pathogenic pathogens can be also on a farm with an area.

In our process, a special carrier, optionally applied, is a bacterial mixture which is a bacterial species known per se but which has not previously been used as a slurry treatment in such a composition.

The treatment is performed with aeration with intensive air intake.

A bacterial mixture is a mixture of Bacillus megatherium (ATTC # B.01091), Bacillus subtilis (ATTC # B.01095), Pseudomonas putida (ATTC # B.01157), Pseudomonas fluorescens (ATTC # B.01102). , Micrococcus roseus (ATTC No. 19172).

The bacterial carrier used is sunflower ash and / or compost and / or comminuted corn stalk from cattle manure, poultry manure and corn straw. The bacterial mixture, optionally applied to a carrier, can be more effective.

Some of the bacteria introduced into the slurry carrier convert the total nitrogen content mainly into ammonia form, the mixture mainly Bacillus megatherium and Bacillus subtilis contribute to the decomposition of organic phosphorus, while the production of Pseudomonas putida siderophor is restricted by pathogen production.

The present invention relates to a process for purifying an aqueous phase of slurry using a microbial inoculum.

The process is characterized in that the aqueous phase is optionally applied to a carrier of a slurry of a slurry of a slurry of a slurry, preferably pig slurry, on a carrier, such as sunflower ash and / or cattle manure, poultry manure and cereal straw.

HU 226 831 Β1

The species contains Bacillus megatherium, Bacillus subtilis, Pseudomonas putida, Pseudomonas fluorescens, Micrococcus roseus in a total colony count of 10 ^{5 to} 10 ⁹ cells / ml, and treatment is carried out at 30-35 ° C with constant aeration, preferably for 10-12 days.

In the process of the present invention, treatment is carried out with ³ to 12% v / v of inoculum per 100 m ^{3 of} slurry. The aeration is preferably carried out for 10 days, preferably with an air flow rate of 0.02-0.08 m ³ per minute.

The air supply is carried out at a pressure of 0.1-0.4 bar.

Preferably, the carrier has a particle size of 0.8-1.9 mm.

The compost used as a carrier preferably has a particle size of 1.4 to 2.6 mm and a degree of maturity measured by Dewar's self-heating test: V.

Preferably, the carrier has a grain size of chopped corn stalk between 2.5 and 3.9 mm.

Preferably, the process according to the invention is carried out by draining 80% of the slurry treated in the aeration basin at the end of the treatment and applying to the remaining treated slurry a further untreated slurry phase.

In order to assure the proper quality of the isolated final product and to ensure proper microbial activity, the amount of vaccine applied to the support in the process is determined by microbiological as well as physico-chemical tests.

The diluted phase treated by the process of the invention is a finished product for field irrigation which is applied directly to the field or subjected to periodic storage.

The following examples illustrate the process of the invention.

Example 1

The slurry fraction (50 m ³ ) separated from the high solids pig slurry phase was treated in a stainless steel reactor.

Previously, a vaccine composition was prepared by applying a 0.9-1.5 mm particle size sunflower ash carrier having a moisture content of 1.36% by weight of a bacterial inoculum mixture having a germ number of 3.2 x 10 ⁸ cells / ml.

The bacterial vaccine mixture is Bacillus megatherium (ATTC # B.01091), Bacillus subtilis (ATTC # B.01095), Pseudomonas putida (ATTC # B.01157), Pseudomonas fluorescens (ATTC # B.01102), Micrococcus roseus species.

The inoculum is added to the reactor in such a quantity that a concentration of 4 l / m ³ slurry is applied.

The vessel aeration was carried out at 8 bar performance compressor or blower with a damper guided through the bottom of the reactor a perforated plastic tube with a 1 mm bore, the intake air quantity of 0.045 m ³ per minute, the distance between the holes is 150 mm.

The reactor is maintained at a temperature of 33-35 ° C with a tubular coil.

Aeration is performed for 10 days.

The number of microbes inoculated with the vaccine is continuously monitored by quantitative culture assay.

Following the biological purification process, 80% of the amount of slurry in the reactor is drained and a new treatment cycle is initiated by adding another untreated slurry liquid phase.

The sludge accumulated at the bottom of the tank can be continuously removed from the conical slurry chamber by a pump or returned to the starting point of the cleaning process.

The parameters of the slurry to be treated and the parameters of the slurry fraction after treatment are shown in Example 4.

Example 2

In all of the procedures of Example 1, the volume of the separated slurry fraction was 100 m ³ .

Biological slurry treatment is carried out in a solid, leak-proof, acid-proof pool.

The other parameters are the same as those described in Example 1, but with a grain size of 2.5 to 3.5 mm and a shredded corn stalk having a moisture content of 1.75% by weight.

Aeration is also carried out on the bottom, but is done by a fine-bubble blower or compressor.

To eliminate adverse environmental conditions, the treatment temperature of 33-35 ° C is provided by direct or indirect heating by covering the pool with a tarpaulin.

Ventilation apertures are formed on the surface of the tarpaulin.

Slurry accumulating at the bottom of the basin is removed with a sludge trimmer or returned to the beginning of the treatment process by forming a sludge and using a lifting pump.

The slurry can also be mixed with the solid fraction to be composted.

Example 3

All were carried out as in Example 1, but the initial slurry fraction had a higher Fecal coliform number than the slurry fraction described in Example 1, so the value was 10 ⁷ germ / ml and the total nitrogen content was above 3500 mg / L.

The treatment procedure parameters are the same as in Example 1, but the compost used is 1.8 to 2.4 mm compost made from 35% v / v cattle manure, 30% v / v poultry manure, 35% v / v cereal straw and used in the Dewar self-heating test V. has a baccalaureate degree.

Intensive aeration is performed for 16 days during treatment.

Example 4

The parameters of the slurry to be treated in Example 1 and the parameters of the treated slurry in Example 1 are shown in

Table 2.

HU 226 831 Β1

Table 1

Name of the test unit Initial control * After 10 days of aeration PH - 8.65 9.85 8.93 ammonium content mg / l 2,494 2,482 301 Sum. nitrogen content mg / l 3,066 2,680 353 Sum. phosphorus content mg / l 379 209 26.9 Total organic matter mg / l 10,880 10,740 4050

Table 2

Name of the test unit Initial control * 10 days aeration Fecal coliform number / 1 ml 1.4χ10 ⁴ 7.2 * 10 ² 0 Enterococcus No. / 1 ml 1.9 * 10 ³ 1.4x10 ² 28

Control *: treatment with a 10-day aeration without the use of a carrier vaccine formulation.

Being a highly concentrated slurry, the ammonium content of the starting material is extremely high, which is significantly reduced during treatment compared to the initial state.

The total nitrogen content of the slurry to be treated was very high (3066 mg / l), which decreased by almost one tenth at the end of the treatment cycle, while the control showed a decrease of 386 mg / l.

The total phosphorus content decreased by 170 mg / l in the control compared to the baseline.

After 10 days of treatment, this value decreased to 1/8 of the control.

There was no statistically significant difference in the organic matter content between the initial slurry and the control.

After the treatment method according to the invention, the organic matter content decreased by about 60%.

In the case of Fecal coliform count, it was already observed in the control procedure that the number of germs decreased by two orders of magnitude;

The Enterococcus count was greatly reduced after the treatment method of the present invention, with a germ number of 28.

Claims (4)

A process for purifying an aqueous phase of slurry using a microbial inoculum, characterized in that the aqueous phase of the slurry, preferably porcine slurry, is optionally applied to a carrier, such as sunflower ash and / or cattle litter and cereal litter and cereal straw. treated with a bacterial inoculum comprising a species of Bacillus megatherium, Bacillus subtilis, Pseudomonas putida, Pseudomonas fluorescens, Micrococcus roseus in a germ count of 10 ^{5 to} 10 ⁹ cells / ml, preferably at 30-35 ° C, preferably with constant aeration, For 10-20 days, carry it out. 2. The method of claim 1, wherein the treatment is carried out with ³ to 12% v / v of inoculum per 100 m ^{3 of} slurry. A process according to claim 1, characterized in that the aeration is carried out for 10 days, preferably with an air flow rate of 0.02-0.08 m ³ per minute. The process according to claim 1, wherein the air supply is carried out at a pressure of 0.1-0.4 bar.