CN110092527B - Environment-friendly process for treating xanthan gum fermentation wastewater - Google Patents

Abstract

The invention belongs to the technical field of environmental protection, and discloses an environment-friendly process for treating xanthan gum fermentation wastewater. The method has simple process operation, and can rapidly and efficiently carry out thorough degradation on pollutants such as ammonia nitrogen and the like.

Description

Environment-friendly process for treating xanthan gum fermentation wastewater

Technical Field

The invention belongs to the technical field of wastewater treatment, and particularly relates to an environment-friendly process for treating xanthan gum fermentation wastewater.

Background

Water is the most valuable property on earth, and is a substance that humans and all living things cannot lack for survival and development. At present, the fresh water resource available for people on the earth is most surface water in an underground water storage layer with the depth of below 800m, which only accounts for 2.6 percent, and actually can be really used as the water resource of human life and production and is only a very small part of the total water quantity of the whole world. The world water crisis has severely threatened human survival, and over one in five people worldwide will be exposed to medium to high water shortage, and this pressure is alerting the world of water shortage. The total amount of water resources in China is the fourth world, but the per capita water volume is only one fourth of the world water volume, and belongs to one of the water-deficient countries, and in addition, the water resources are unevenly distributed in different regions in different seasons and the water pollution of main rivers and lakes further aggravate the crisis of available water resources in China. The main pollution factors in the four sea areas of the south China sea, the yellow sea, the Bohai sea and the east China sea all comprise ammonia nitrogen, sulfide and active phosphate. In recent years, the number of red tides in the sea area of China is increasing, and the high-incidence areas of the red tides are concentrated in the sea area of the east China, and the number of red tides and the cumulative occurrence area respectively account for 69% and 77% of the total sea area. Large-area red tides appear in Bohai Bay, Zhejiang south China, and other sea areas.

The xanthan gum fermentation wastewater is derived from several working procedures of xanthan gum fermentation and extraction processes, and contains a large amount of COD, ammonia nitrogen, sulfides, organic matters and the like. There are various methods for denitrification of wastewater, such as stripping, breakpoint chlorination, ion exchange and biological denitrification. Biological denitrification is the most economically viable process in view of the current state of the art and practice. Moreover, with the continuous development of biotechnology, the biological denitrification method is gradually improved, and is the preferred treatment method for urban sewage with the largest pollution level and the most complex water quality. Biological denitrification refers to the process of finally converting ammonia nitrogen and organic nitrogen into nitrogen under the participation of nitrobacteria and denitrifying bacteria, thereby achieving the aim of denitrification. The denitrification process comprises two reaction processes of nitrification and denitrification. The nitrification process is that ammonia state and organic nitrogen are oxidized into nitrate (NO3-N) under the action of nitrite bacteria and nitrate bacteria. The denitrification process is that the nitrate is reduced into nitrogen under the denitrification action of denitrifying bacteria, namely the denitrification process is finished.

The applicant has long studied the treatment of xanthan gum fermentation wastewater, and the chinese patent technology "CN 104313004A, a preparation for treating xanthan gum production wastewater" discloses a preparation for treating xanthan gum production wastewater, which is a carrier and a composite microbial agent according to the ratio of 2:1, the carrier is chitosan, the preparation contains more bacterial strains, the culture operation process is difficult, and the preparation cannot be repeatedly utilized. The Chinese patent technology 'CN 106882909A, environmental protection process for treating xanthan gum fermentation wastewater' also uses a biological agent, the biological agent is prepared by mixing four bacteria and a carrier, the carrier is prepared by sintering raw materials such as zeolite, kaolinite, starch, chitosan and the like, the adhesive force is good, the biological agent can be suspended in water, the sludge yield is reduced, and the biological agent can be repeatedly utilized by calcination, but the biological agent cannot completely degrade ammonia nitrogen, and a large amount of nitro nitrogen and nitroso nitrogen are still contained in the water body.

Immobilized biotechnology is a new technology rapidly developed in the 60's of the 20 th century, and it is a new technology that locates free cells or enzymes in a limited spatial region by chemical or physical means, so that they keep activity and can be recycled. In the beginning of the 80 s of the 20 th century, the immobilized biotechnology is gradually applied at home and abroad to treat industrial wastewater and decompose organic pollutants which are difficult to biodegrade, and the staged progress is achieved. In recent years, immobilized biotechnology has been a research hotspot in the field of water treatment. Because the theoretical retention time of microorganisms or enzymes can be improved to be infinite by the immobilized biotechnology, the microorganism can not be flushed out even if the dilution rate is very high, namely, the volume load can be randomly adjusted and controlled by the water inflow, so that the production efficiency can be greatly improved. The advantages are that: compared with the common activated sludge method, the treatment capacity is 1-3 times higher, the effluent quality is good, the organic load resistance and the hydraulic impact resistance are stronger, and the operation cost can be reduced; the anti-toxicity effect is stronger in the aspect of degrading toxic pollutants. More promising is to mix and embed high-efficiency mixed microorganism system as a microbial inoculum, which can greatly improve the treatment efficiency of the existing biological treatment system.

Disclosure of Invention

The invention aims to solve the defects of the prior art, provides an environment-friendly process for treating xanthan gum fermentation wastewater, can thoroughly treat pollutants such as ammonia nitrogen in the wastewater, and is simple in process and convenient to operate.

The invention is realized by the following technical scheme:

an environment-friendly process for treating xanthan gum fermentation wastewater uses a biological agent, and is characterized in that the biological agent comprises paracoccus denitrificans, clostridium perfringens and halomonas elongata.

Further, the process comprises the following steps: removing large solid matters from the wastewater by a filter screen, then carrying out precipitation treatment in a primary sedimentation tank, and then entering an acid-base regulation tank to regulate the pH value to 6-7; then the mixture enters a biological reaction tank, biological agents are added according to the amount of 10-20g of the liquid per cubic meter, the mixture is treated for 96-120h, the treated mixture is discharged into a disinfection tank through a water outlet, and the treated mixture is discharged after disinfection.

Preferably, a water outlet of the biological reaction tank is provided with a screen for preventing the biological preparation from flowing out; the intercepted particle size of the screen is 0.5 mm.

Further, the biological agent is prepared according to the following steps:

step 1) mixing kaolin and bentonite according to a mass ratio of 2:1, adding the mixture into a ball mill, carrying out ball milling for 30min, drying the mixture for 15min at 80 ℃, then sieving the dried mixture by a 100-mesh sieve, and collecting undersize products;

step 2) uniformly mixing polyvinyl alcohol, attapulgite, urea, water and undersize materials according to the mass ratio of 3:5:7:70:100, then putting the mixture into a granulator for granulation to obtain wet granules with the diameter of 1-2mm, then placing the wet granules in a resistance furnace for drying at 80 ℃ for 30min, then placing the wet granules in a resistance furnace for calcining at 1000 ℃ for 30min, and naturally cooling to obtain ceramsite;

step 3), mixing the microbial inoculum A and the ceramsite according to the proportion of 1L: mixing the components according to the proportion of 2kg, culturing for 6h at the temperature of 30 ℃, then sequentially adding the microbial inoculum B and the sodium alginate aqueous solution, stirring uniformly, dropwise adding the calcium chloride aqueous solution while shaking, and standing for 12h after dropwise adding is finished to prepare the biological preparation.

Preferably, in the step 3), the volume ratio of the microbial inoculum A, the microbial inoculum B, the sodium alginate aqueous solution and the calcium chloride aqueous solution is 3-4:3-4:1-2: 5-7.

Preferably, the concentration of the sodium alginate aqueous solution is 40-50 g/L.

Preferably, the concentration of the calcium chloride aqueous solution is 20-30 g/L.

Preferably, the microbial inoculum A is Halomonas elongata.

Preferably, the concentration of Halomonas elongata is (1-5). times.10⁸cfu/ml。

Preferably, the microbial inoculum B is prepared from paracoccus denitrificans and clostridium perfringens according to the ratio of 2-3: 1-2 by volume ratio.

Preferably, the concentration of paracoccus denitrificans and clostridium perfringens is (1-5) multiplied by 10⁸cfu/ml。

Preferably, the paracoccus denitrificans is ATCC 13543; the clostridium perfringens adopts ATCC 10543; the Halomonas elongata is ATCC 33173.

The invention can obtain the bacterial liquid with the required concentration by a conventional culture method, is not an innovative point of the invention and is not detailed.

The advantages achieved by the present invention mainly include, but are not limited to, several aspects:

in the preparation process of the carrier, the selected kaolin and bentonite have stable chemical properties, and the kaolin and the bentonite have a plurality of shell holes, porous structures, high porosity and strong adsorption performance; the attapulgite can be used as an adhesive, the polyvinyl alcohol is used as a dispersing agent, and the urea is used as a pore-forming agent; the ceramsite obtained by granulating the substances has the advantages of high strength, high porosity, density close to that of water, suspension state and good dispersibility.

Firstly, embedding Halomonas elongata with an anaerobic denitrification function into the inside of a ceramsite aperture, so that the method is an ideal anaerobic environment and is suitable for anaerobic denitrification; embedding paracoccus denitrificans and clostridium perfringens with aerobic nitrification function outside and on the surface of the aperture, wherein the paracoccus denitrificans and the clostridium perfringens are in an aerobic environment and are suitable for aerobic nitrification; the situation that denitrifying bacteria and nitrifying bacteria compete for dissolved oxygen under aerobic conditions is avoided, and the excessive proliferation of the denitrifying bacteria in the presence of an organic carbon source is also avoided; the nitrite generated by the direct reduction and nitration reaction of the denitrifying bacteria reduces the requirements on oxygen and organic matters; the method forms a short-range virtuous cycle, namely ammonia nitrogen- (nitro nitrogen + nitroso nitrogen) -nitrogen, thereby completely degrading ammonia nitrogen pollutants.

The biological agent can maintain high-concentration biomass in the device when used for treating wastewater, thereby improving the treatment load and reducing the volume of the treatment device; the density of the biological agent is equivalent to that of the waste water and is in a suspension state; realizes simultaneous nitrification and denitrification, and has the advantages of high denitrification speed, high efficiency, simple process, convenient operation and control, and the like.

Drawings

FIG. 1: degradation of ammonia nitrogen by different biological agents;

FIG. 2: degradation of nitro nitrogen + nitroso nitrogen by different biological agents.

Detailed Description

Those skilled in the art can modify the process parameters appropriately to achieve the desired results with reference to the disclosure herein. It is expressly intended that all such similar substitutes and modifications which would be obvious to one skilled in the art are deemed to be included in the invention. While the products and methods of this invention have been described in terms of preferred embodiments, it will be apparent to those of skill in the art that variations and modifications, or appropriate alterations and combinations, of the products and methods described herein may be made and utilized without departing from the spirit, scope, and spirit of the invention. For a further understanding of the present invention, reference will now be made in detail to the following examples.

Example 1

The biological agent for treating xanthan gum fermentation process wastewater is prepared according to the following processes:

mixing kaolin and bentonite according to the mass ratio of 2:1, adding the mixture into a ball mill filled with a ball milling medium (5mm silicon carbide balls, the mass ratio of material balls is l:5) for ball milling for 30min, drying the mixture for 15min at 80 ℃, then sieving the dried mixture by a 100-mesh sieve, and collecting undersize products;

uniformly mixing polyvinyl alcohol, attapulgite, urea, water and undersize materials according to the mass ratio of 3:5:7:70:100, then putting into a granulator for granulation to obtain wet granules with the diameter of 1mm, then placing in a resistance furnace for drying at 80 ℃ for 30min, then placing in a resistance furnace for calcining at 1000 ℃ for 30min, and naturally cooling to obtain ceramsite;

and (3) mixing the microbial inoculum A and the ceramsite according to the proportion of 1L: 2kg of the components are mixed, cultured for 6 hours at the temperature of 30 ℃,

then sequentially adding the microbial inoculum B and a 40g/L sodium alginate aqueous solution, stirring uniformly, dropwise adding a 20g/L calcium chloride aqueous solution while shaking, and standing for 12h after dropwise adding is finished to prepare a biological agent; the volume ratio of the microbial inoculum A to the microbial inoculum B to the sodium alginate aqueous solution to the calcium chloride aqueous solution is 3:3:1: 5.

The microbial inoculum A is Halomonas elongata with the concentration of 1 multiplied by 10⁸cfu/ml；

Said bacteriumAgent B is prepared from paracoccus denitrificans and clostridium perfringens according to the ratio of 2:1, the concentration of the paracoccus denitrifican and the clostridium perfringens is 1 multiplied by 10⁸cfu/ml。

The paracoccus denitrificans is ATCC 13543; the clostridium perfringens adopts ATCC 10543; the Halomonas elongata is ATCC 33173.

Example 2

The biological agent for treating xanthan gum fermentation process wastewater is prepared according to the following processes:

mixing kaolin and bentonite according to the mass ratio of 2:1, adding the mixture into a ball mill filled with a ball milling medium (5mm silicon carbide balls, the mass ratio of material balls is l:5) for ball milling for 30min, drying the mixture for 15min at 80 ℃, then sieving the dried mixture by a 100-mesh sieve, and collecting undersize products;

uniformly mixing polyvinyl alcohol, attapulgite, urea, water and undersize materials according to the mass ratio of 3:5:7:70:100, then putting into a granulator for granulation to obtain wet granules with the diameter of 2mm, drying at 80 ℃ for 30min, then putting into a resistance furnace for calcining at 1000 ℃ for 40min, and naturally cooling to obtain ceramsite;

and (3) mixing the microbial inoculum A and the ceramsite according to the proportion of 1L: 2kg of the components are mixed, cultured for 6 hours at the temperature of 30 ℃,

then sequentially adding the microbial inoculum B and a 50g/L sodium alginate aqueous solution, stirring uniformly, dropwise adding a 30g/L calcium chloride aqueous solution while shaking, and standing for 12h after dropwise adding is finished to prepare a biological agent;

the volume ratio of the microbial inoculum A to the microbial inoculum B to the sodium alginate aqueous solution to the calcium chloride aqueous solution is 4:4:2: 7.

The microbial inoculum A is Halomonas elongata with the concentration of 3 multiplied by 10⁸cfu/ml；

The microbial inoculum B is prepared from paracoccus denitrificans and clostridium perfringens according to the weight ratio of 3: 2, the concentration of the paracoccus denitrificans and the clostridium perfringens are both 2 multiplied by 10⁸cfu/ml。

The paracoccus denitrificans is ATCC 13543; the clostridium perfringens adopts ATCC 10543; the Halomonas elongata is ATCC 33173.

Example 3

The invention discloses index detection of ceramsite.

Porosity: measuring the porosity of the sample by using a boiling method of GB/T1966-1996;

mechanical strength: the bending strength of the porous ceramic is measured by using the GBTl965/1996 test method for the bending strength of the porous ceramic.

The specific indexes are shown in table 1:

TABLE 1

Group of	Porosity%	Mechanical strength Mpa	Density g/ml
				Example 1	72.8	14.6	1.04
Example 2	70.6	15.3	1.08

Therefore, the ceramic particle carrier has the porosity of more than 70 percent, the aperture of 0.1-10 microns, easy processing, large strength, high porosity, density close to that of water, suspension state and good dispersibility in waste water, and is beneficial to quickly adsorbing and treating pollutants.

Example 4

Control group: bioremediation formulation prepared in patent CN106882909A (example 1);

the experimental group is inventive example 1.

The treatment process is the same: removing large solid matters from the wastewater by a filter screen (the aperture is 5 mm), then carrying out precipitation treatment in a primary sedimentation tank, and then entering an acid-base regulation tank to regulate the pH to 6.5 (the indexes of various pollutants are COD1553mg/L, ammonia nitrogen 149mg/L and SS 92 mg/L); then the mixture enters a biological reaction tank, biological agents are added according to the amount of 20g of the liquid per cubic meter, the mixture is treated for 96 hours, the mixture is discharged to a disinfection tank through a water outlet, and the mixture is discharged after disinfection; a water outlet of the biological reaction tank is provided with a screen for preventing the biological preparation from flowing out; the intercepted particle size of the screen is 0.5 mm.

The wastewater batches are the same, the content of the nitro nitrogen and the nitroso nitrogen and the content of the ammonia nitrogen are detected at different time points (24, 48,72,96 and 120 hours), as shown in figure 1-2, the content of the ammonia nitrogen in a control group and an experimental group is rapidly reduced along with the increase of the treatment time, the content reduction range of the nitro nitrogen and the nitroso nitrogen in the control group is obviously inferior to that of the experimental group, when the wastewater is treated for 96 hours, the content of the ammonia nitrogen in the control group and the ammonia nitrogen in the experimental group are both reduced to be below 10mg/L, but the content of the nitro nitrogen and the nitroso nitrogen in the control group is close to 50mg/L, the content of the nitro nitrogen and the nitroso nitrogen in the experimental group is only 2.3mg/L, the treatment time is continuously increased, and the treatment effect is not greatly influenced. Obviously, the biological agent of the experimental group is more efficient, and the treatment of ammonia nitrogen is more thorough, mainly because the anaerobic denitrifying bacteria inside the ceramsite play a role.

Example 5

The biological agent of the invention has the effect of treating wastewater.

The treatment process referred to example 4. Sampling and measuring COD, ammonia nitrogen, SS and data of nitro nitrogen and nitroso nitrogen; and setting a control group, and detecting the compatibility effect of each strain and the carrier in the microbial preparation:

control group 1: paracoccus denitrificans + clostridium perfringens;

control group 2: clostridium perfringens + halomonas elongata;

control group 3: paracoccus denitrificans + halomonas elongata;

experimental groups: paracoccus denitrificans + clostridium perfringens + sarmonas elongata;

the detection results of COD, ammonia nitrogen SS and nitro nitrogen + nitroso nitrogen after treatment of each group are shown in a table 2:

TABLE 2

Group of	Control group 1	Control group 2	Control group 3	Experimental group
					COD（mg/L）	97.3	63.2	47.5	12.9
NH3-N（mg/L）	21.1	13.2	10.4	3.1
					SS（mg/L）	13.4	15.6	9.1	3.8
Nitro-and nitroso-nitrogen (mg/L)	43.7	15.6	11.8	2.3

According to the biological preparation, three types of microorganisms are selected, the number of strains is small, the compatibility of the strains is reasonable, the synergistic performance is good, and a special embedding mode is adopted, so that the situation that denitrifying bacteria and nitrifying bacteria compete for dissolved oxygen under an aerobic condition is avoided, and the situation that the denitrifying bacteria are over-proliferated in the presence of an organic carbon source is also avoided; the denitrifying bacteria directly reduce the nitric acid nitrogen and the nitrous acid nitrogen generated by the nitration reaction, so that the requirements on oxygen and organic matters are reduced; the method forms a short-range virtuous cycle, and can rapidly and efficiently carry out thorough degradation on ammonia nitrogen pollutants.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (2)

1. An environment-friendly process for treating xanthan gum fermentation wastewater comprises the following steps: removing large solid matters from the wastewater by a filter screen, allowing the wastewater to enter a primary sedimentation tank for sedimentation treatment, and then allowing the wastewater to enter an acid-base regulation tank for regulating the pH value to 6-7; then the mixture enters a biological reaction tank, biological agents are added according to the amount of 10-20g of the liquid per cubic meter, the mixture is treated for 96-120h, the treated mixture is discharged into a disinfection tank through a water outlet, and the treated mixture is discharged after disinfection;

a water outlet of the biological reaction tank is provided with a screen for preventing the biological preparation from flowing out; the intercepted particle size of the screen is 0.5 mm;

the biological agent is prepared according to the following steps:

step 1) mixing kaolin and bentonite according to a mass ratio of 2:1, adding the mixture into a ball mill, carrying out ball milling for 30min, drying the mixture for 15min at 80 ℃, then sieving the dried mixture by a 100-mesh sieve, and collecting undersize products;

step 2) uniformly mixing polyvinyl alcohol, attapulgite, urea, water and undersize materials according to the mass ratio of 3:5:7:70:100, then putting the mixture into a granulator for granulation to obtain wet granules with the diameter of 1-2cm, then placing the wet granules in a resistance furnace for calcination at 1000 ℃ for 30-40min, and naturally cooling to obtain ceramsite;

step 3), mixing the microbial inoculum A and the ceramsite according to the proportion of 1L: mixing 2kg of the components, culturing for 6 hours at 30 ℃, then sequentially adding the microbial inoculum B and the sodium alginate aqueous solution, stirring uniformly, dropwise adding the calcium chloride aqueous solution while shaking, and standing for 12 hours after dropwise adding is finished to prepare the biological agent;

the microbial inoculum A is Halomonas elongata, and the microbial inoculum B is prepared from paracoccus denitrificans and clostridium perfringens according to the weight ratio of 2-3: 1-2 by volume ratio;

in the step 3), the volume ratio of the microbial inoculum A, the microbial inoculum B, the sodium alginate aqueous solution and the calcium chloride aqueous solution is 3-4:3-4:1-2: 5-7.

2. The process of claim 1, wherein the concentration of Halomonas elongata, Paracoccus denitrificans and Clostridium perfringens are each (1-5) x 10⁸cfu/ml。

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