JP5148764B2 - Ground improvement method using microorganisms - Google Patents

Description

  The present invention relates to a ground improvement method, and more particularly, to a ground improvement method for increasing the liquefaction resistance of a ground by a microbial metabolite.

  The ground liquefaction phenomenon is a phenomenon in which sand ground with a high groundwater level behaves like a liquid during an earthquake. As a result, it is known that buildings constructed in the shape of sandy ground may cause unequal subsidence and structures with low specific gravity in the ground (such as sewer pipes) may occur, causing significant damage. ing. On the other hand, the conditions for liquefaction of the ground include that the ground is saturated with water or close to saturation, and that the pore water pressure increases due to vibration and the shear strength of the ground decreases (by Yoshiaki Yoshimi) "Liquefaction of sand ground 2nd edition" Technique Hall 1991: Non-Patent Document 1).

  Various measures for preventing liquefaction of the ground during an earthquake have been proposed. For example, Japanese Patent Application Laid-Open No. 2008-57247 (Patent Document 1) proposes a method for constructing underground wall bodies that are continuous in a wall shape on both sides of a pipeline laid on the ground.

  Japanese Patent Application Laid-Open No. 10-18308 (Patent Document 2) includes a continuous surrounding wall constructed around the foundation structure of a building, and a plurality of retaining walls constructed at predetermined intervals along the outer surface of the surrounding wall. It proposes a method to prevent liquefaction by effectively suppressing shear deformation of the foundation ground of the building by constructing a liquefaction prevention structure of the building foundation ground.

  Both of the methods described in Patent Documents 1 and 2 prevent liquefaction by constructing a concrete wall or the like in the ground and restraining deformation of the ground, but the construction cost is high, and It will be very expensive to remove.

  Japanese Patent Laid-Open No. 2003-119762 (Patent Document 3) discloses that a well is provided in a target ground, and an aqueous solution of an alkali metal salt in which a chloride containing at least one of alkali and alkaline earth metal is dissolved in water is injected into the well. The present invention proposes a method of injecting an aqueous carbonate solution containing carbonate ions into a well to form a hardly soluble salt containing at least one of alkali and alkaline earth metal inside the target ground. This method improves fluidization resistance by filling the gaps between the particles constituting the ground with a hardly soluble salt, but requires an enormous amount of chloride and aqueous carbonate solution corresponding to the volume of the target ground.

  Japanese Patent Laying-Open No. 2007-211537 (Patent Document 4) discloses a technique for reducing the water saturation of the ground by injecting fine bubbles into the ground and making it difficult to cause liquefaction. In the case of this technology, in order to maintain the unsaturated state of the ground, it is necessary to continue the bubble injection, which requires continuous maintenance costs, and the bubble injection system requires high earthquake resistance. There is also.

On the other hand, as a ground improvement technique using microorganisms, a ground improvement method for reducing the water permeability of the ground by injecting an organic nutrient source, a calcium salt, and a pH buffer (Japanese Patent Laid-Open No. 2006-169940: Patent Documents) 5) and a method for improving oil renovation by constructing impermeable walls in the soil with microorganisms capable of producing bacterial cellulose (Japanese Patent Laid-Open No. 2001-321164: Patent Document 6). However, neither of the techniques described in Patent Documents 5 and 6 is a technique for preventing liquefaction of the ground. All of the techniques described in these publications make the ground impervious, and are in themselves contradictory techniques for lowering the saturation of the ground and making fluidization difficult to occur.
Yoshimi Yoshiaki "Sand Liquefaction 2nd Edition" Technique Hall 1991 JP 2008-57247 A Japanese Patent Laid-Open No. 10-18308 JP 2003-119762 A JP 2007-2111537 A JP 2006-169940 A JP 2001-321164 A

  The object of the present invention is to solve the above-mentioned problems of the prior art. Further, the construction cost and the maintenance cost are low, and the invention can be applied to a site before construction and an underground ground of an existing building. To provide a method for easily increasing the liquefaction resistance of the ground and improving the ground to be difficult to liquefy during an earthquake.

  In order to achieve the above object, the present invention provides an organic substance and / or an inorganic substance as nutrients necessary for the metabolism of microorganisms having an action of increasing the liquefaction resistance existing in the ground, thereby metabolizing the microorganisms. Is a ground improvement method for enhancing the liquefaction resistance of the ground by the metabolite of the microorganism and / or the expanded cell aggregate.

  In the present specification, the microorganism refers to minute organisms such as prokaryotes and eukaryotes, and is used to include bacteria, actinomycetes, filamentous fungi, protozoa, etc. that inhabit (or can live in) soil. . Metabolism is used as a term encompassing substance metabolism and energy metabolism, and includes catabolism, fermentation, aerobic respiration, anaerobic respiration, and assimilation. Nutrient refers to substances necessary for the metabolism of microorganisms that use organic and inorganic substances alone or in combination, depending on the production of the desired metabolite, but organic substances include carbohydrates, sugars, proteins, amino acids, lipids, Examples of inorganic substances such as fatty acids and lower fatty acids include nitrogen compounds and phosphorus compounds. Apart from these, it is necessary to supply electron acceptors (oxygen, nitrate, etc.) necessary for the respiration of microorganisms when the ground environment is insufficient.

  The method of supplying nutrients to the ground is not limited to a specific method as long as it does not affect the structure that is the target of liquefaction prevention measures. As an example, nutrients and useful cells are injected from the borehole or well provided near the liquefaction-prevented ground and / or the vicinity (by any method formed on the ground by excavation) or by a recharge method or press-fitting method. To do. In addition, before construction of the building, the target ground can be excavated and mixed with necessary microorganisms and nutrients and then backfilled. Liquefaction resistance refers to the nature of the ground that is difficult to liquefy during an earthquake, and in the present invention, depending on the microorganism used and the metabolic reaction, among the requirements for liquefaction, mainly the decrease in water saturation and viscosity of the ground. Increased resistance to liquefaction.

  In the present invention, in order to increase the liquefaction resistance of the ground, both nutrients and microorganisms may be supplied into the ground. When the ground is improved by metabolites of microorganisms that naturally exist in the target ground, only the nutrients of the microorganisms may be supplied to the ground. However, if both nutrients and microorganisms are supplied to the ground, they are present in the target ground. It is also possible to improve the ground by metabolites of microorganisms that do not.

  As a method of reducing the water saturation of the ground, it is also possible to generate nitrogen gas using microorganisms (group). As the microorganism, denitrifying bacteria, which are bacteria that promote the production of nitrogen, can be used. A denitrifying bacterium refers to a nitrate-reducing bacterium that has the ability to reduce nitrate ions to nitrogen, and examples include bacteria belonging to the genus Pseudomonas, Paracoccus, and Thiobacillus. In this case, the nutrient is a nitrogen compound which finally becomes nitrate ions or nitrate ions, and the metabolite is nitrogen gas. Nitrogen gas produced by the denitrifying bacteria's metabolism stays in the ground, thereby reducing the water saturation of the ground and increasing the liquefaction resistance.

  As a method of reducing the water saturation of the ground, carbon dioxide gas is generated using microorganisms (groups). The microorganism effectively used in the present specification refers to a microorganism having a metabolic mechanism that generates carbon dioxide using oxygen as an electron acceptor, and includes not only aerobic bacteria but also facultative aerobic bacteria and obligate aerobic bacteria. Also encompass. Since a large number of such microorganisms exist in the ground, it is not necessary to introduce the cells having the ability to increase liquefaction resistance according to claim 1 to the ground, but oxygen is insufficient in the ground. Therefore, it is necessary to supply oxygen. For oxygen supply, air sparging or a sustained-release oxygen supply agent (magnesium peroxide or the like) can be used. The metabolite produced by the aerobic bacteria is carbon dioxide gas, and the liquefaction resistance is increased by reducing the water saturation of the ground by the carbon dioxide gas retained in the ground.

    As a method of increasing the liquefaction resistance by increasing the viscosity in the pore water of the ground, a highly viscous metabolite (biopolymer) is generated using microorganisms (group). Biopolymers produced by microorganisms have various properties, but here, bacteria that produce biopolymers that are insoluble or sparingly soluble in water and have the highest possible viscosity in pore water are desirable. . In order to prevent long-term liquefaction, it is necessary to increase the viscosity in pore water over the long term using persistent biodegradable insoluble biopolymer producing bacteria. The supply method is effective. Examples of insoluble polymer-producing bacteria include microorganisms described in Registration 3895654. The Enterobacter sp. CJF-002 strain described in the patent is a facultative anaerobic bacterium that can be cultured in large quantities using inexpensive sugars, and can also be used in the present invention. In this case, the nutrient is a saccharide or a composition containing a saccharide, and the metabolite is a biopolymer.

  The increase in the viscosity of the pore water in the ground is also promoted by an increase in the amount of microbial biomass present in the pore water, which forms a biofilm or the like. A biofilm is a film-like high-viscosity body that is formed by metabolites when microorganisms grow into soil gaps. The existence of biofilms is known as a phenomenon in which high concentrations of microorganisms form aggregates in polysaccharides and polymers to close gaps and cause clogging of wells. Since biofilm has a higher specific gravity and viscosity than pore water, liquefaction resistance increases due to the presence of biofilm. In addition, since the amount of biofilm produced is considered to be approximately proportional to the number of microorganisms, aerobic conditions, which are oxidation-reduction conditions that facilitate the acquisition of microorganism energy, are advantageous. Usually, since there is a correlation between gas generation and biofilm generation, it is possible to enhance the liquefaction resistance capability under the conditions of claim 3 in which nutrient (oxygen) is supplied by the same technique as biogas.

  The microorganism is not particularly limited as long as it produces a biofilm. The essential source to activate them is oxygen, and the accompanying nutrient sources include carbohydrates, saccharides, proteins, amino acids, lipids, higher fatty acids, lower fatty acids, etc. as organic substances, and nitrogen compounds, phosphorus compounds, etc. as inorganic substances Select and supply to the ground. The metabolites are various polymer compounds that form a biofilm, and the biofilm in the ground increases the viscosity of the ground during an earthquake to increase liquefaction resistance. Biofilm-producing bacteria, for example, various species belonging to the genus Acetobacter, Alkagenes, Pseudomonas, Agrobacterium, Rhizobium, Sphaerotilus, Sarsina, Achromobacter, Aerobacter, Azotobacter and Zoogrea It is a fungus.

  The supply of the necessary nutrients into the ground can be performed by a liquefaction-prevented ground and / or a well provided in the vicinity of the ground, or a nutrient supply facility having an equivalent function, and if necessary, a pumping well Establish a facility such as to circulate pore water in the saturated soil of the target ground.

  According to the present invention, the construction cost and the maintenance cost are low, and it can be applied to the site before construction and the underground ground of an existing building, and it becomes possible to increase the liquefaction resistance of the ground by a method that is easy to remove. .

  Hereinafter, specific embodiments of the present invention will be described based on examples. However, the present invention is not limited to the examples described below, and the examples are described to help the understanding of the invention. It goes without saying that it is not too much.

FIG. 1 is a conceptual diagram showing equipment for implementing the ground improvement method according to the present invention.
In FIG. 1, a building 500 is constructed on the ground of a saturated ground 100 that is a target for increasing liquefaction resistance. The first well 200 is excavated around the building, and an aqueous solution mixed with nitrate and / or organic matter stored in the nitrate / organic matter storage tank 400 is injected into the first well 200 by the water injection pump 300. On the other hand, the second well 220 is excavated to another place around the building (for example, a position on a diagonal line with the first well 200), and groundwater is pumped out by the pumping pump 320. The pumped-up groundwater may be returned to the water injection pump 300 and circulated.

  By comprising in this way, nitrate and / or organic substance are supplied to the saturated ground 100. FIG. Therefore, denitrifying bacteria in the ground directly under the structure can be supplied with electron donors (hydrogen) supplied from organic matter and nitrate ions as electron acceptors, and nitrogen gas is generated by the denitrification reaction, Diffuses into saturated pore water. As a result, the degree of saturation of the ground is lowered and the liquefaction resistance is increased. Since nitrogen will gradually dissipate from the surface over time, it is desirable that the nitrate and / or organic supply be carried out continuously or intermittently.

FIG. 2 is a photograph showing a state in which microorganisms are grown in the ground. Although there are naturally 10 ⁷ cells / g of microorganisms in the normal saturated ground shown in the left photograph, as a result of creating a suitable environment for the growth of microorganisms (Fig. 2, right photograph), the number is about 100 times The metabolic activity is also greatly increased. That is, in an environment that has created an environment suitable for the growth of microorganisms, it is confirmed that a large number of microorganisms occupy the soil interstitial water, and these form a biofilm to increase liquefaction resistance by increasing the viscosity in the ground interstitial water. FIG. 3 shows an example of gas generation by the microorganism shown in FIG. 2, but it is shown that the ratio of gas to water increases as the number of cells in a unit volume increases. That is, it has been shown that the growth of microorganisms decreases the saturation of the ground and increases the liquefaction resistance. FIG. 3 shows data related to the gas generation of bacteria using fermentation of saccharides, but the above-mentioned tendency can be found in the same way in the case of using organic substances instead of saccharides and also in the generation of gases other than the use of fermentation. is there.

  With the same configuration shown in FIG. 1, biopolymers can be produced by activating the metabolism of Enterobacter sp. CJF-002 strain (described above), which is a facultative anaerobic microorganism. The produced polymer is desirably a hardly degradable insoluble biopolymer that can stably increase the viscosity of the ground over a long period of time. In that case, the nutrient supply can be suspended while the effect of the biopolymer is maintained. A photograph of an insoluble biopolymer produced by a microorganism is shown in FIG. 4 for reference.

  FIG. 5 is a conceptual diagram showing a case where oxygen and nutrients are supplied to promote metabolism of aerobic microorganisms or facultative aerobic microorganisms according to one embodiment of the present invention. The same components as those in FIG. In FIG. 5, a compressor 420 is newly provided. The compressor 420 forcibly supplies air to the saturated ground (sparging). By doing so, oxygen is supplied to the groundwater, and an environment suitable for the growth and activation of aerobic microorganisms is created. As a method for supplying nutrients other than oxygen, “JP 2005-131533 In-situ purification system for contaminated groundwater” is effective. If carbon dioxide and biofilms are generated by the growth of aerobic microorganisms, they will increase the liquefaction resistance of the ground.

  At this time, if a method of supplying nutrient water containing microbubbles to the ground using a microbubble generating device instead of the compressor 420 is used, the metabolism of the aerobic microorganisms is promoted and the liquid of the ground is metabolized as described above. While increasing the liquefaction resistance, the liquefaction resistance can also be increased by direct desaturation by microbubbles in the ground. Microbubbles also have the advantage that the oxygen concentration in the groundwater can be maintained at a high value over a long period of time by gradually dissolving in the groundwater.

The conceptual diagram which shows the ground improvement method based on this invention Photograph showing the growth of microorganisms in saturated ground based on the present invention Graph showing the number of microorganisms in a unit volume and the gas / water ratio Photograph of a biopolymer based on the present invention The conceptual diagram which shows the ground improvement method based on this invention

100 Saturated ground 200, 220 First well, second well 300, 320 Water injection pump, water pump 400 Nitrate / organic matter storage tank 420 Compressor 500 Building

Claims (3)

  By supplying nutrients necessary for the metabolism and / or growth of microorganisms existing in the ground to promote the metabolism and / or growth of the microorganisms, the metabolite of the microorganisms and / or the grown cell aggregates A ground improvement method for increasing the liquefaction resistance of the ground, wherein the microorganism reduces the water saturation of the ground.   The ground improvement method according to claim 1, wherein the nutrient is a nitrate compound or a nitrogen compound which finally becomes nitrate ion.   The ground improvement according to claim 1 or 2, wherein the supply of the necessary nutrients into the ground is performed by a liquefaction-prevented ground and / or a well provided in the vicinity of the ground, or a nutrient supply facility having an equivalent function thereto. Construction method.