RU2526993C1 - Method of producing biogas from animal waste - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: method of producing biogas from animal waste includes pretreatment of an organic substrate by bringing moisture content thereof to 90%, followed by crushing the substrate to particle size of 0.5-0.7 cm. An organic catalyst is added, fermentation is carried out in an anaerobic medium and biogas is collected. The organic catalyst used is dairy wastes in amount of 5-10% of the mass of the organic substrate. Fermentation in an anaerobic medium is carried out at temperature of 17-22°C.

EFFECT: invention intensifies the process of methane fermentation of manure to increase output of biogas and increase content of methane therein.

2 cl, 1 dwg

Description

The invention relates to methods for processing organic waste using biotechnological processes and obtaining biogas.

Biogas is a cheap and affordable way to generate energy. At present, a sufficiently large number of biogas production technologies have been developed and applied, based on the use of various options for temperature, humidity, microbial concentration, duration of the reaction, etc. However, today the issue of finding the most effective, cheap and affordable ways to intensify the process of biogas production at various temperature conditions remains relevant.

A known method of anaerobic digestion of liquefied organic waste and a device for its implementation (patent RU 2073401, application No. 92009236, priority date 12/01/1992, publication date 02/20/1997, class A01C 3/00, C02F 3/00). The essence of the known invention lies in the fact that anaerobic digestion of organic waste is carried out sequentially in the external and internal chambers of the digester, and mixing of the fermented waste in the outer chamber is carried out by feeding organic waste introduced into the menthol tank.

A disadvantage of the known invention is that conditions that increase the methane content in biogas are not used.

A known method of producing biogas from animal excrement (patent WO 2012/152266, application PCT / DE2012 / 100124, publ. 11/15/2012, CL 5/02). This decision was made initially in Germany and in 116 countries of the world and involves several stages of fermentation to separate methane. Liquid manure or chicken droppings are used as the initial substrate. The first stage of fermentation occurs within 1 to 4 days with the addition of an enzyme, and then a solution of ammonia. Then separation occurs gas containing about 50% CO _2, H ₂ S, NH _3. Then, repeated fermentation is carried out from 10 to 30 days at a temperature of 35 ° C and above, a certain acidity, and then biogas containing methane up to 75% is re-separated.

A disadvantage of the known solution is the length of the process and the complexity of its application, for example, by small farms. In addition, a sufficiently high reaction temperature is maintained.

For the prototype adopted the known method of methane digestion of manure (patent RU 2413408, application No. 2009138011, priority date 10/15/2009, publication date 03/10/2011, CL A01C 3/00, C02F 11/04, C02F 3/34 ) The essence of the method lies in the fact that methanogenesis cultures are introduced into the liquid substrate while maintaining the acidity of the medium in the range of pH 6.5-7.8 and temperatures up to 37.5 ° C.

The disadvantage of this method is the cost of heat energy for heating and maintaining the reactor at a temperature of 37.5 ° C, which is unacceptable for regions with a cold climate.

Manure contains all the bacteria necessary for methane fermentation, therefore, there is no need to additionally introduce methane generating structures, it is only necessary to provide the bacteria that are already in optimal conditions for their life.

The technical result of the present invention is the intensification of the process of methane fermentation of manure with an increase in biogas yield and a high methane content in it.

A method for producing biogas from animal excrement is proposed, which includes pretreatment of an organic substrate by bringing it to a moisture content of 90%, followed by grinding, introducing an organic catalyst, fermenting in an anaerobic environment, collecting biogas.

The difference is that the substrate is crushed to a particle size of 0.5 to 0.7 cm, and milk production waste in the amount of 5% to 10% by weight of the organic substrate is used as an organic catalyst, and fermentation in an anaerobic medium is carried out at a temperature of 17 ° C to 22 ° C.

Another difference is that whey is used as waste from dairy production.

The term "biogas", as used in the formula, refers to the gas produced by the decomposition of organic material in the absence of oxygen. The described type of gas - biogas mainly includes methane and carbon dioxide, in small amounts of hydrogen sulfide.

The term "organic substrate" involves the use of manure obtained as a result of the activity of farm animals and poultry.

The term "anaerobic digestion" refers to the description of the decomposition of an organic substrate by microorganisms that carry out their activity in an oxygen-free environment, with the accompanying synthesis of methane, carbon dioxide and small amounts of hydrogen sulfide.

The term “milk production waste” implies the use of any production residues containing waste after processing and processing dairy raw materials in production, including individual organic and mineral elements of milk, such as whey, buttermilk, etc.

Waste from dairy production is currently partially used. For example, whey is disposed of in large volumes. At the same time, dairy waste due to its rich chemical composition has all the necessary trace elements and vitamins to create a favorable environment for methanogenic bacteria. Each type of microorganisms of anaerobic reproduction is characterized by a specific need for macrosubstances, microelements and vitamins. The concentration and availability of these components affect the growth rate and activity of populations. It is this property of bacteria that was used in the present invention. The result of the vital activity of these bacteria is biogas containing methane. Therefore, improving the living conditions of methane-forming bacteria, the above technical result can be achieved.

For this, the organic substrate is pre-moistened up to 90% and ground to a particle size of 0.5 to 0.7 cm. Milk whey is introduced in a volume of 5% to 10%, which is used as a “top dressing” for bacteria. This creates optimal conditions for the fermentation process. Fermentation is carried out strictly within the specified temperature range from 17 ° C to 22 ° C.

Scientific developments are confirmed by experimental studies confirming the influence of the essential features of the claimed claims on obtaining a technical result.

The studies were conducted at the Kemerovo State Agricultural Institute on the basis of the problematic research laboratory of AgroBioTechnologies in laboratory biogas plants with a volume of 20 liters. Litter of cattle was used as an organic substrate. To exclude the influence of the quality of the initial substrate on the research result, each batch of manure was formed under certain feeding regimes of the herd.

Initially, the substrate was brought to a moisture level of 90%. Then it was crushed to a particle size of 0.5 to 0.7 cm. Studies have shown that the size of the solid particles of the substrate is of fundamental importance, affecting the rate of biogas release from cattle manure at different temperatures. Particle size affects the ability of bacteria to “absorb” more, while emitting a larger volume of biogas. The particle size indicated in the formula is optimal for a given temperature regime, which is confirmed by studies.

During the experiment, whey was added in the following volumes by weight of the loaded organic substrate:

1%, 5%, 10% and 15%. At each stage, the selection and analysis of the content of samples of biogas was carried out.

The effect of various concentrations of whey on the biogas yield during anaerobic treatment of cattle manure is shown in Fig. 1. The result when using a control sample without adding whey is shown 1, a sample with added serum in an amount of 1% by weight of organic substrate 2, a sample with added serum in an amount of 5% 3, 10% of serum is shown 4, 15% of serum is shown 5.

The most optimal concentration of whey is the introduction of whey in an amount of from 5% to 10%. For process stability, studies have shown that a balanced ratio of micronutrients and micronutrients is needed. Using this concentration, the highest biogas yield was obtained at relatively low fermentation temperatures. The methane content in the sample of released biogas was 58%. A stable biogas yield was obtained already on the 7th day of fermentation. Similar results are known at higher temperature conditions of the fermentation of the organic substrate.

Using more whey does not improve the overall yield of biogas, including methane. Therefore, increasing the concentration of whey is unprofitable.

Application of the proposed method for producing biogas from animal excrement will make it possible to obtain a cheap source of energy in conditions of even small farms, without the use of expensive catalysts and enzymes. At the same time, organic fertilizer is obtained - an effluent, environmentally friendly, easily accessible to plants.

Claims (2)

1. A method of producing biogas from animal excrement, including pretreatment of an organic substrate by bringing it to 90% moisture, followed by grinding, introducing an organic catalyst, fermentation in an anaerobic environment, collecting biogas, characterized in that the substrate is ground to a particle size of from 0.5 to 0.7 cm, and as an organic catalyst use waste from dairy production in a volume of from 5% to 10% by weight of the organic substrate and fermentation in anaerobic environment is carried out at a temperature of from 17 ° C to 22 ° . 2. The method according to claim 1, characterized in that whey is used as milk production waste.

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