KR20210044076A - Fishery by-product acid fermentation broth and preparation method thereof - Google Patents

Abstract

Disclosed are a fishery byproduct acid fermentation liquid capable of producing biogas through an anaerobic merging process by mixing the same with sewage sludge, and a preparation method of the fishery byproduct acid fermentation liquid. The fishery byproduct acid fermentation liquid according to an embodiment of the present disclosure is obtained by anaerobic acid fermentation of a fishery byproduct with a mixture of water and rice bran or corncob powder as an external carbon source.

Description

Fishery by-product acid fermentation broth and preparation method thereof {Fishery by-product acid fermentation broth and preparation method thereof}

Disclosed content relates to a fermented aquatic by-product acid fermentation broth obtained by anaerobic acid fermentation and a method for preparing the same.

Unless otherwise indicated in the specification, the contents described in this identification item are not prior art to the claims of this application, and description in this identification item is not admitted to be prior art.

The amount of sewage sludge generated in Korea continues to increase by 5.9% every year, and most of the generated sewage sludge is landfilled (17.9%), incinerated (30.6%), and recycled (51.6%). Land and energy costs are required. To reduce sewage sludge, various methods such as thermal hydrolysis, hydraulic kinetics, solubilization technology by ultrasonic waves, and medium-temperature digestion are applied as a fire extinguishing method, but these methods have high power consumption, installation cost, and operation cost, and the cost of adding chemicals is incurred. Therefore, many attempts are being made to combine anaerobic digestion tanks that can increase the reduction rate of sewage sludge at low cost and produce biogas as a by-product.

This anaerobic digester integration process can reduce the wastewater sludge by increasing the sludge digestion efficiency of the anaerobic digester, thereby reducing the sludge treatment cost, and the produced biogas can be used as an alternative energy source, so it is very economical. In addition, the combined sewage process can reduce construction costs by using the existing digester, and increase the digestion efficiency of the digester by introducing organic matter into the sewage treatment plant operating under low load. There is an advantage in that organic acids can be supplied as an external carbon source required for denitrification treatment.

Until now, researches on producing biogas using food waste and livestock manure have been actively conducted, but studies on sludge reduction and biogas production using fishery by-products are hardly found by our knowledge.

The world's seafood production is increasing every year, and according to FAO (Food and Agriculture Organization of the United Nations, 2018), seafood production in 2016 is about 171 million tons. In 2017, Korea's marine aquatic product production amounted to 2743,000 tons, an increase of 14.5% compared to the previous year, and aquatic by-products, which occur 20%-80%, depending on the type of fishery product, are also increasing. Fishery by-products are wastes that are incidentally generated during the production, distribution, processing and sale of seafood such as fish bones, internal organs, and blood. More than 620,000 tons of fishery by-products are generated annually in Korea, and the aquatic by-products generated are mainly processed into fish meal and feed and recycled, but most of the fish by-products generated in small-scale sashimi centers and homes are treated in the form of food waste. The treatment of aquatic by-products has a high socio-economic cost. Various problems have arisen in the process of disposing of fishery by-products, and untreated fishery by-products lead to coastal neglect, illegal landfilling, and ocean dumping, as well as wastewater leakage and odor during the disposal process, damaging the natural landscape or causing environmental pollution. Is causing. This causes problems such as damage to the urban landscape, occurrence of odor, and reproduction of pests. However, when such aquatic by-products are reused or converted into resources, it is possible to solve the various problems presented above and create new growth engines through new added value.

According to previous studies, for aquatic by-products, 7.0 ~ 12.5% N ₂ , 2.8 ~ 5.9% P ₂ O ₅ , 0.6 ~ 1.8% K ₂ O, 1.8 ~ 5.1% CaO, 0.1 ~ 0.4% MgO, 0.3 ~ 0.8% Na ₂ O It contains about 81 to 92% of organic matter and 62 to 79% of moisture, so it has very good conditions for the growth of microorganisms. Therefore, aquatic by-products have a lot of potential to be converted into biogas through anaerobic digestion.

Currently, in the merger process of anaerobic tanks using aquatic by-products, most of the solids are filtered, pulverized, and then directly introduced into the anaerobic digester. However, according to previous studies, if aquatic by-products are added directly to an anaerobic digester, the digestion efficiency of the digester is rather affected by the rapid drop in pH due to local acid fermentation, the scum conversion due to the difference in acid fermentation rate, and the salt content of the aquatic by-products. It has an inhibitory effect.

1. Korean Patent Registration No. 10-1011973 (2011.01.25.) 2. Korean Patent Publication No. 10-2013-0086671 (2013.08.05.)

The disclosed content improves the above problems that occur when the marine by-products are directly injected into the anaerobic digester in producing biogas through a combined process with sewage sludge, enables mixed digestion even at high loads, and reduces sludge as well as reduces biogas. It is intended to provide a fermentation broth of aquatic by-product acid and a method of manufacturing the same so that the methane content can be improved.

In addition, it is not limited to the above-described technical problems, and it is obvious that another technical problem may be derived from the following description.

The disclosed contents describe as an example an acid fermentation broth obtained by anaerobic acid fermentation of a mixture containing aquatic by-products, water, and rice bran or corn cob powder as an external carbon source.

According to a preferred feature of the disclosed content, the acidity of the acid fermentation broth of the aquatic by-product is obtained from pH 2 to pH 4, characterized in that the acid fermentation broth.

When the above-described fermentation broth of aquatic by-products is mixed with sewage sludge and undergoes anaerobic digestion, the side effects of mixed digestion without fermentation of aquatic by-products are reduced, as well as the reduction of sewage sludge and biogas with improved methane content. Can be produced.

The effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a sequence of a method for preparing a fermented aquatic by-product acid fermentation broth using rice bran or corn cob powder according to the disclosed contents.
2 is a graph of changes in pH according to acid fermentation of aquatic by-products to which rice bran or corncob powder is added.
3 is a graph showing the change in the amount of acetic acid generated according to acid fermentation of a fishery by-product to which rice bran or corncob powder is added.

The aquatic by-product acid fermentation broth according to an embodiment of the disclosure is a material obtained by anaerobic acid fermentation of a mixture containing rice bran or corncob powder as water and an external carbon source in aquatic by-products.

Fishery by-products Fishery by-products used in the acid fermentation broth are composed of fish bones, intestines, and blood, and are 7.0 ~ 12.5% N ₂ , 2.8 ~ 5.9% P ₂ O ₅ , 0.6 ~ 1.8% K ₂ O, 1.8 ~ 5.1% CaO, 0.1 ~ 0.4% MgO, 0.3 ~ 0.8% Na ₂ O are contained, and organic matter is about 81 ~ 92%, moisture is 62 ~ 79%. It can be converted to biogas.

The water used for the acid fermentation broth of aquatic by-products is not otherwise limited, and general tap water that has not undergone special treatment may be used.

Rice bran, which is used in the fermentation broth of aquatic by-products, is a mixture of peel, seed skin, and algae layer, which is formed when making polished rice by grinding brown rice.It is also called rice bran. It contains a lot.

Corncob powder, which is used in the fermentation broth of aquatic by-products, is made from corncob, which is an agricultural by-product that is produced when corn grains are produced, in a powder form. According to reports, 100 kg of corn kernels are produced, and 18 kg of corn cobs are generated, which is used as an external carbon source to reduce sewage sludge and generate acid fermentation broth that can produce biogas by using corn cobs, which is a large amount of agricultural waste. Dry corncob contains 57.8% carbon, which acts as an external carbon source.

In general, the acid fermentation process proceeds slowly due to salt and fat components contained in aquatic by-products. When the acid fermentation broth of aquatic by-products is prepared, a large amount of sugar contained in rice bran or corn cob powder is added by adding rice bran or corn cob powder as an external carbon source. It plays an important role in promoting acid fermentation, shortening the fermentation period and increasing the acetic acid content.

Hereinafter, the manufacturing method will be described with reference to FIG. 1 as follows.

As shown in FIG. 1, a method for preparing a fermented aquatic acid fermentation broth for high-efficiency biogas production according to an embodiment of the disclosed subject matter undergoes a pre-treatment step (S1) and a pre-treatment step of removing foreign substances contained in the aquatic by-product. The anaerobic acid fermentation of the mixture through the pulverization step (S2) of pulverizing aquatic by-products and the mixing step (S3) and the mixing step of adding water and rice bran or corncob powder to the pulverized aquatic by-products to form a mixture It consists of a fermentation step (S4).

The pretreatment step (S1) is a step of removing plastic, vinyl, gravel, sand, yarn, etc., which are unsuitable for anaerobic acid fermentation of aquatic by-products.

The pulverization step (S2) is a step in which the anaerobic acid fermentation can be carried out more actively by making the aquatic by-product particles to 3 mm or less using a pulverizer.

The mixing step (S3) is a step of mixing 100 parts by volume of aquatic by-product, 5 to 15 parts by volume of water, and 5 to 15 parts by volume of rice bran or corncob powder with an external carbon source. If the volume of water is less than 5, the viscosity is high and fermentation is difficult to proceed smoothly, and if the volume of water exceeds 15, the relative ratio of aquatic by-products decreases and the concentration of acetic acid in the fermentation broth decreases, resulting in less biogas production. Accordingly, the volume portion of the water is an optimal range for smoothly proceeding acid fermentation, increasing the throughput of aquatic by-products, and increasing the production of biogas.

Rice bran used in the mixing step (S3) is filtered through an 80 mesh sieve to remove contaminants before mixing with aquatic by-products, and then dried in an oven at 70 to 90° C. for 18 to 26 hours to sterilize contaminating microorganisms. At temperatures lower than 70°C, contaminated microorganisms are not sterilized, and at 90°C or higher, bacteria necessary for the acid fermentation step are killed. Therefore, it is preferable to perform sterilization at 70 to 90°C. If the drying time is less than 18 hours, the moisture contained in the rice bran is not completely dried, and drying for more than 26 hours kills fermentation microorganisms, so 18 to 26 hours are preferable. After sterilization is completed, the dried rice bran is mixed with aquatic by-products, followed by acid fermentation of aquatic by-products.

For the corn cob powder used in the mixing step (S3), remove the corn kernels and wash the remaining corn cobs with water to wash off organic substances and contaminants adhering to the surface, and then place the washed corn cobs in an oven at 70 ~ 90℃. It is dried for 68 to 75 hours inside and undergoes a pretreatment process to sterilize contaminating microorganisms. Contaminated microorganisms are not sterilized at temperatures lower than 70°C, and bacteria necessary for the acid fermentation step are killed at temperatures above 90°C, so it is preferable to sterilize at a temperature of 70 to 90°C. Less than 68 hours, the moisture of the corncob is completely removed. Drying for more than 75 hours without removal will kill fermentation microorganisms, so 68 to 75 hours is preferable. After cutting the dried corncobs into 0.5 ~ 2cm size, put them in a grinder to prepare them in a powder form. After mixing the corncobs in powder form with aquatic by-products, fermentation of aquatic by-products is carried out.

In the fermentation step (S4), a mixture containing aquatic by-products, water, rice bran or corn cob powder is placed in a 10L circular reactor, and anaerobic acid fermentation is performed while stirring at 120 to 160 rpm under a temperature of 50 to 60°C without pH adjustment. This is the step to make. Anaerobic microorganisms are sensitive to environmental changes and do not adjust their pH. If the stirring temperature is less than 50°C, acid fermentation is too slow, and if it exceeds 60°C, the cost increases due to energy consumption. Therefore, a temperature of 50 to 60°C is preferable in terms of reducing energy consumption while maintaining proper activity. The stirring speed is preferably in the range of 120 to 160 rpm, since acid fermentation occurs actively, the acid fermentation stabilization time is short, and the amount of acetic acid generated is the largest.

The fermentation step (S4) takes about 4 to 6 days, and the stabilization time of the fisheries by-product acid fermentation broth (FFB) is the concentration of carbohydrates, proteins, and organic acids, which are the major dissolved components of the fisheries by-product acid fermentation broth. It is based on the point in time when is almost constant. The acidity of the acid fermentation broth obtained through the acid fermentation step is pH 2 to pH 4, which is filtered through a 3 mm sieve to remove solids and then stored at room temperature.

In order to compare the acid fermentation stabilization time according to the presence or absence of rice bran or corn cob powder added to the acid fermentation process of aquatic by-products, Comparative Examples and Examples were prepared.

In the comparative example, rice bran or corn cob powder was not added to the acid fermentation process, Example 1 was to add rice bran powder to the acid fermentation process, and Example 2 was to add corn cob powder to the acid fermentation process.

Example 1 Example 2 Comparative example pH 3.4 after 4 days 3.7 after 7 days 3.6 after 10 days Acetic acid generation amount (g/L) 10.0 after 4 days 10.0 after 7 days 7.8 after 10 days Stabilization period 4-5 days 6-7 days 9-10 days

Referring to Table 1 and Figure 2, the time when acid fermentation is stabilized is determined as the point at which the pH change disappears. In Example 1, acid fermentation becomes stable after 4 to 5 days, and Example 2 is after 6 to 7 days. While acid fermentation is stable, acid fermentation is stable after about 10 days in Comparative Example.

Referring to Table 1 and FIG. 3, when the acid fermentation process is stabilized, the amount of acetic acid generated in Examples 1 and 2 is about 2 g/L higher than in Comparative Examples. Since acetic acid generated in the acid fermentation process becomes the main raw material for generating methane in biogas, the greater the amount of acetic acid is, the greater the amount of biogas is produced and the greater the effect of reducing sewage sludge. In Examples 1 and 2, the reason why the acid fermentation was stabilized quickly and the amount of acetic acid produced was large is that the sugar contained in rice bran and corncob powder promoted acid fermentation.

The acid fermentation broth stored at room temperature is mixed with sewage sludge to produce high-efficiency biogas. Currently, the combined process of an anaerobic tank using aquatic by-products uses a method of filtering solids, pulverizing them, and putting them directly into the anaerobic digester. According to this method, it is not possible to stabilize methanogenic bacteria that are sensitive to temperature changes and have a slow growth rate, and a digestive tank due to rapid pH decrease due to local acid fermentation, scum conversion due to differences in acid fermentation rate, and salt contained in aquatic by-products. There are side effects that hinder the digestion efficiency of the body. However, in the case of acid fermentation of aquatic by-products, since there are many types of anaerobic bacteria in the acid generation stage, even if the temperature changes, the temperature is not affected by the microorganisms corresponding to the temperature, so the effect of temperature is not large. Therefore, it is possible to shorten the proliferation period of methanogenic bacteria in the anaerobic digestion tank. The various side effects that occur when the aquatic by-product is directly added can be eliminated in advance. As a result, when the acid fermentation broth of aquatic by-products is added, it can be mixed and digested at a higher load, so that a larger amount of aquatic by-products can be treated, and the most energy can be recovered by increasing the amount of methane produced in biogas.

Claims (8)

Acid fermentation broth obtained by anaerobic acid fermentation of a mixture containing aquatic by-products, water, and rice bran or corn cob powder as an external carbon source.
The method according to claim 1,
The mixture is a marine by-product acid fermentation liquid, characterized in that it comprises 100 parts by volume of aquatic by-product, 5 to 15 parts by volume of water, and 5 to 15 parts by volume of rice bran or corn cob powder as an external carbon source.
The method according to claim 1,
The acidity of the aquatic by-product acid fermentation broth is pH 2 to pH 4, characterized in that the aquatic acid fermentation broth.
A pretreatment step of removing foreign substances contained in aquatic by-products;
A pulverizing step of pulverizing the aquatic by-products passed through the pretreatment step;
A mixing step of forming a mixture by adding rice bran or corn cob powder as water and an external carbon source to the aquatic by-product that has undergone the pulverization step; And
A method for producing a fermented aquatic acid by-product comprising a fermentation step of anaerobic acid fermentation of the mixture passed through the mixing step.
The method of claim 4,
In the mixing step, 100 parts by volume of aquatic by-product, 5 to 15 parts by volume of water, and 5 to 15 parts by volume of rice bran or corn cob powder as an external carbon source are added and mixed.
The method of claim 4,
The rice bran in the mixing step is dried for 18 to 26 hours at a temperature of 70 to 90°C after removing foreign substances.
The method of claim 4,
The method for producing a fermented aquatic acid by-product acid fermentation broth, characterized in that the corn cob powder of the mixing step is pulverized after washing the corn cob to remove foreign substances, drying at a temperature of 70 to 90°C for 68 to 75 hours.
The method of claim 4,
In the fermentation step, the mixture is anaerobic acid fermentation while stirring at 120 to 160 rpm at a temperature of 50 to 60°C.

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