JP3756323B2 - Ground improvement method - Google Patents

Description

【００１６】
このように構成された地盤改良装置においては、まず、切換弁２２により水ポンプ２６とスイベル２０とを連通させる。次いで、モニター１６の最下端のノズルから下方に水を噴射しつつ、ボーリングマシン１４は、ロッド部１２を回転させて、これを地中に挿入する。
【００１７】
地中の所定の位置までロッド部１２を進めた後に、切換弁２２により超高圧ポンプ２４とスイベル２０とを連通させる。次いで、モニター１６においても、その側壁に形成されたノズル（図示せず）から硬化材などを噴射できるように弁（図示せず）を切り換えた後に、ボーリングマシン１４は、ロッド部１２を回転させつつ、これを引き抜く。グラウドミキサー３０には水およびキレート剤が供給されているため、硬化材、キレート剤および水の混合物が、超高圧ポンプ２４から送出され、切換弁２２およびスイベル２０を介して、モニター１６の側部に形成されたノズルから、上記混合物が、たとえば２００kgf／cm^２程度の超高圧にて噴射される。その一方、コンプレッサ２８からも圧縮空気が送出され、これがスイベル２０を介して、上記ノズルの近傍に配置された第２のノズルから、圧縮空気が、たとえば７kgf／cm^２程度の圧にて噴射される。
ロッド部１２が引き抜かれるのにしたがって、圧縮空気および上記混合物が噴射された領域に、混合物からなる地盤改良体（図１の符号４０参照）が造成され、かつ、圧縮空気により、ロッドと土壌との空隙を介して上記領域の土壌が、地上に排出される。
【００１８】
本実施の形態においては、上記混合物はキレート剤を含有しているため、この領域に存在する重金属がキレート化され不溶化される。さらに、上記領域にはセメントミルクなどの硬化材からなる改良体が造成されるため、不溶化された重金属は、これにより固化される。したがって、本実施の形態によれば、セメントなどの硬化材に透水性があっても、有害物質が不溶化されるため、改良体の外側の土壌に、これが再溶出するおそれを著しく減ずることができ、かつ、有害物質が固化されるため、有害物質の拡散のおそれを著しく減ずることが可能となる。すなわち、本実施の形態によれば、土壌中に重金属が再溶出したり或いは再開放するおそれを著しく減ずることが可能となる。
また、この実施の形態によれば、地上に排出される排土にもキレート剤が含まれるため、排土中に含まれる重金属をキレート化して不溶化することが可能となる。したがって、排土、排水或いは改良体からの有害重金属の溶出を排水基準や水質基準以下に抑えることが可能となる。さらに、このように重金属をキレート化して不溶化し、かつ、このような重金属を含有する領域を硬化材にて固化した地盤改良体を、基礎杭などに使用することが可能となる。
【００１９】
次に、第２の実施の形態にかかる地盤改良工法につき説明を加える。図２は、この工法を実施するための装置の概略を示す図である。第２の実施の形態にかかる地盤改良装置１００は、本発明をコラムジェットグラウト工法に適用したものである。なお、図２において、図１の構成部分と同様のものには同一の符号を伏している。図２に示すように、この装置１００は、ロッド部１１２とコラムマシン１１４とを備えている。なお、コラムジェットグラウト工法では、ロッド部１２は、トラッククレーン（図示せず）により釣り下げられている。ロッド部１１２は、最下部に配置され、水、圧縮空気、硬化材をそれぞれ噴射するノズルを有している。より詳細には、最下部には硬化材を噴射するノズルが配置され、その上部に、水、圧縮空気をそれぞれ噴射するノズルが配置されている。モニター１１６およびロッド１１８は、硬化材の経路、水の経路および圧縮空気の経路を備えた三重管構造となっている。硬化材の経路は、スイベル１２０およびグラウトポンプ３６を介して、グラウトミキサー３０に連結されている。また、水の経路は、スイベル１２０および超高圧ポンプ２４を介してグラウトミキサー２６に連結され、圧縮空気の経路は、スイベル１２０を介してコンプレッサ２８に連結されている。
【００２０】
第１の実施の形態と同様に、グラウトミキサー３０には、キレート剤を収容したタンク３２および水ポンプ３４と連結され、キレート剤および水が供給されるようになっている。
このように構成された地盤改良装置においては、まず、ボーリング装置を用いてケーシングパイプ（図示せず）を埋め込んで、ガイドホール１２２を形成する。次いで、ロッド部１１２をガイドホール１２２に挿入し、コラムマシン１１４によりロッド部１１２を回転させてこれを引き抜きつつ、上側に位置するノズルより、超高圧ポンプ２４およびスイベル１２０を介して供給された、たとえば４００kgf／cm^２の高圧水と、コンプレッサ２８およびスイベル１２０を介して供給された、たとえば７kgf／cm^２の圧縮空気が噴射される。これにより、所定の領域の土壌が切削される。さらに、圧縮空気により切削された土壌はガイドホール１２２を通って地上に排出される。その一方、グラウトポンプ３６およびスイベル１２０を介して、下端のノズルより、硬化材、キレート剤および水の混合物が、たとえば、２０kgf／cm^２の圧にて噴射される。これにより、上側のノズルからの水および圧縮空気にて切削された領域に、硬化材およびキレート剤を含む改良体を造成することができる。このようにロッド部１１２が引き抜かれるのにしたがって、上記領域に混合物からなる改良体（図２の符号１４０参照）が造成される。
【００２１】
第２の実施の形態においても、上記混合物はキレート剤を含有しているため、この領域の存在する重金属がキレート化されて不溶化され、かつ、改良体中にて固化される。したがって、本実施の形態によれば、土壌中に重金属が再溶出したり或いは再開放するおそれを著しく減ずることが可能となる。
特に、この実施の形態によれば、硬化材を充填すべき領域の土砂と硬化材との置換・混合時に発生する硬化材混入土砂の排泥液中の重金属を不溶化することができ、かつ、硬化材を地盤中で硬化させることで、地盤中の重金属の地下水への溶出速度の低下をなすことが可能となる。
【００２２】
次に、本発明の第３の実施の形態にかかる地盤改良工法につき説明を加える。この実施の形態においても、地盤改良装置２００は、本発明をコラムジェットグラウト工法に適用している。第２の実施の形態との相違点は、切削に使用する水にキレート剤を混合した点にある。したがって、図３に示すように、第３の実施の形態にかかる地盤改良装置２００においては、キレートタンク３２は、水ポンプ２６から供給される水と、キレート剤とを混合するミキサー２０２に連結されている。したがって、この実施の形態においては、ロッド部のモニター１６の上側のノズルより、ミキサー２０２、超高圧ポンプ２４およびスイベル１２０を介して供給された水とキレート剤との混合物、並びに、コンプレッサ２８およびスイベル１２０を介して供給された圧縮空気が、それぞれ噴射され、これにより、所定の領域の土壌が切削される。この実施の形態においては、土壌の切削のためにキレート剤を含む水を、ノズルの一方より、たとえば、４０００kgf／cm^２にて噴射することになる。
【００２３】
この実施の形態によれば、切削のためにキレート剤を含む水を使用するため、切削されて圧縮空気により地上に排出された排土中に含まれる重金属も、キレート剤によりキレート化することが可能となる。特に、この実施の形態によれば、硬化材を充填すべき領域を造成するとき、すなわち、土壌を切削するときに発生する硬化材混入土砂の排泥液中に含まれる重金属の不溶化、および、地盤・地下水中の重金属の不溶化をなすことが可能となる。また、硬化材噴射時の硬化材混合土砂の排泥液中に含まれる重金属を不溶化することができ、かつ、硬化材を地盤中で硬化させることで、地盤中の重金属の地下水への溶出速度の低下をなすことが可能となる。
【００２４】
次に、本発明の第４の実施の形態にかかる地盤改良工法につき説明を加える。この実施の形態においては、いわゆる水切削により、改良体を造成すべき領域に超高圧の水を噴射してから、ロッド部を引き上げる際に硬化材を噴射している。図４に示すように、この実施の形態にかかる地盤改良装置３００と、第１の実施の形態にかかる地盤改良装置１０との相違点は、キレートタンク３２から供給されるキレート剤と水ポンプ２６から供給される水とを混合するミキサー３０２が設けられ、かつ、切換弁２２が、ミキサー３０２或いはグラウトミキサー３０の何れかと、超高圧ポンプ２４とを連通させるように配置されている点である。
【００２５】
このように構成された地盤改良装置３００において、ロッド部１２の挿入時すなわち切削時には、切換弁２２によりミキサー３０２と超高圧ポンプ２４とが連通する。ボーリングマシン１４によりロッド部１２は、回転しつつ地中に挿入され、かつ、モニター１６の側壁に形成されたノズルから、水とキレート剤との混合物が、たとえば４０００kgf／cm^２の超高圧にて噴射され、かつ、コンプレッサ２８から供給された圧縮空気が、たとえば７kgf／cm^２の圧にて噴射される。これにより、所定の領域（図４（ａ）の符号３０４参照）の土壌が柔らかくなるとともに、その領域中の重金属がキレート化される。地中の所定の位置までロッド部１２を進めた後に、切換弁２２によりグラウトミキサー３０と超高圧ポンプ２４とを連通させ、次いで、ボーリングマシン１４は、ロッド部１２を回転させつつこれを引き抜く。このときに、モニター１６の側壁のノズルから、水と硬化材との混合物が高圧にて噴射され、また、圧縮空気が所定の圧にて噴射される。したがって、図４（ｂ）に示すように所定の領域３４０に、硬化材を含む改良体を造成することができる。なお、水切削により柔らかくなった土壌は、圧縮空気により、および、改良体の造成にしたがって、地上に向かって押し出され排出される。この実施の形態においては、まず、水切削の際に、キレート剤を含む水を用いて、所定の領域の重金属をキレート化して、これを不溶化し、次いで、硬化材により固化している。また、キレート化された重金属の一部は、地上に排出される。
【００２６】
特に、この実施の形態によれば、硬化材を充填すべき領域を造成するとき、すなわち、水切削のときに発生する土砂排泥液中の重金属を不溶化することが可能となる。また、硬化材噴射時の硬化材混合土砂の排泥液中に含まれる重金属を不溶化することができ、かつ、硬化材を地盤中で硬化させることで、地盤中の重金属の地下水への溶出速度の低下をなすことが可能となる。
【００２７】
次に、本発明の第５の実施の形態にかかる地盤改良工法につき説明を加える。この実施の形態においても、水切削を用いている。図５に示すように、この実施の形態にかかる地盤改良装置４００は、第４の実施の形態にかかる地盤改良装置３００と、キレートタンク３２からキレート剤がグラウトミキサ３０に供給されるようになっており、したがって、ミキサー３０２が省略されている点で相違している。この実施の形態にかかる地盤改良装置４００においては、ロッド部１２の挿入時すなわち切削時には、切換弁２２により水ポンプ２６と超高圧ポンプ２４とが連通するため、モニター１６の側壁に形成されたノズルから、水が超高圧にて噴射され、かつ、コンプレッサから供給された高圧空気が、所定の圧にて噴射される。これにより、所定の領域（図５（ａ）の符号４０４参照）の土壌が柔らかくなる。地中の所定の位置までロッド部１２を進めた後に、切換弁２２によりグラウトミキサー３０と超高圧ポンプ２４とを連通させ、次いで、ボーリングマシン１４は、ロッド部１２を回転させつつこれを引き抜く。このときに、モニター１６の側壁のノズルから、水、硬化材およびキレート剤との混合物が高圧にて噴射され、また、圧縮空気が所定の圧にて噴射される。したがって、図４（ｂ）に示すように所定の領域３４０に含まれる重金属がキレート剤によりキレート化され、かつ、硬化材により固化される。このようにして、所定の領域に改良体を造成することができる。
【００２８】
本発明は、以上の実施の形態に限定されることなく、特許請求の範囲に記載された発明の範囲内で、種々の変更が可能であり、それらも本発明の範囲内に包含されるものであることは言うまでもない。
たとえば、上記実施の形態においては、いわゆるジェットグラウト工法に本発明を適用しているが、これに限定されるものではなく、機械攪拌方式にも本発明を適用できることはいうまでもない。たとえば、外周にスパイラルが形成され、かつ、下端部に、上側および下側の二組の硬化材吐出口と、攪拌翼とが設けられた攪拌軸を回転させて貫入し、所定の深度まで貫入する。次いで、下側の吐出口より、硬化材とキレート剤との混合物を吐出して先端部を処理し、その後に、攪拌翼を回転させて引き抜きつつ、上側の吐出口より上記混合物を吐出して、所定の範囲に改良体を造成すれば良い。或いは、攪拌軸を回転させて貫入する際に、上側および下側の吐出口の少なくとも一方から、硬化材キレート剤を吐出しても良いことはいうまでもない。
【００２９】
また、上記実施の形態においては、ジェットグラウト工法のうち、ＪＳＧ工法およびコラムジェットグラウト工法に本発明を適用したが、他のジェットグラウト工法、たとえば、ＣＣＰ工法や３Ｓ−ＭＡＮ工法にも本発明を適用できることは明らかである。
【００３０】
さらに、上記実施の形態においては、キレート剤の溶液をキレートタンクに収容して、これをミキサーなどに供給しているが、これに限定されるものではなく、キレート剤の粉体を、硬化材と水との混合物（スラリー）などに混合しても良い。
【００３１】
また、上記第４の実施の形態においては、水とキレート剤との混合物、および、圧縮空気により水切削をなしたが、これに限定されるものではなく、水とキレート剤との混合物のみにより水切削をなしてもよい。また、上記第５の実施の形態においては、水と圧縮空気とにより水切削をなしたが、水のみにより水切削をなしてもよい。
さらに、本明細書において、一つの部材の機能が、二つ以上の物理的部材により実現されても、若しくは、二つ以上の部材の機能が、一つの物理的部材により実現されてもよい。
【００３２】
【発明の効果】
本発明によれば、重金属などの有害物質を不溶化し、かつ、これを固定化して、土壌中に再溶出したり或いは再開放されるおそれの小さい地盤改良工法を提供することが可能となる。また、本発明によれば、重金属などの有害物質を捕捉かつ固定化しつつ、基礎杭などに使用可能な改良体を造成できる地盤改良工法を提供することが可能となる。
【図面の簡単な説明】
【図１】 図１は、本発明の第１の実施の形態にかかる地盤改良工法を実施するための装置の概略を示す図である。
【図２】 図２は、本発明の第２の実施の形態にかかる地盤改良工法を実施するための装置の概略を示す図である。
【図３】 図３は、本発明の第３の実施の形態にかかる地盤改良工法を実施するための装置の概略を示す図である。
【図４】 図４は、本発明の第４の実施の形態にかかる地盤改良工法を実施するための装置の概略を示す図である。
【図５】 図５は、本発明の第５の実施の形態にかかる地盤改良工法を実施するための装置の概略を示す図である。
【符号の説明】
１０ 地盤改良装置
１２ ロッド部
１４ ボーリングマシン
１６ モニター
１８ ロッド
２０ スイベル
２２ 切換弁
２４ 超高圧ポンプ
２６、３４ 水ポンプ
２８ コンプレッサ
３０ グラウトミキサー
３２ キレートタンク[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a ground improvement method, and more particularly, to a ground improvement method for creating an improved body on a ground including soil contaminated with a hazardous substance such as heavy metal.
[0002]
[Prior art]
In recent years, contamination by harmful substances such as heavy metals contained in soil has become a problem. For example, these harmful substances may be ingested by the human body by penetrating into groundwater. Therefore, various techniques for fixing such harmful substances in the soil and preventing the penetration of groundwater and the like have been proposed.
For example,
(1) A method to dig up the soil and remove the contaminated part,
(2) A method of injecting cement milk into contaminated soil and solidifying it,
(3) A method of melting and solidifying the metal by heating the contaminated soil to a high temperature, or
(4) Method of injecting chelating agent (chelating agent) to capture and insolubilize harmful substances
Etc. are considered. Alternatively, as another method, Japanese Patent Application Laid-Open No. 8-281246 has mixed organic thickeners such as CMC, polyacrylamide, and alginic acid into inorganic reducing agents such as ferrous sulfate and metal powder. A technique for adding a material to soil containing hexavalent chromium is disclosed.
[0003]
[Problems to be solved by the invention]
However, in the method (1), it is necessary to transfer the contaminated soil to a stable disposal site, and it is necessary to secure the disposal site and to move it. In addition, in order to create foundation piles and the like, once contaminated soil is discharged, and then foundation piles are created, there is also a problem that the number of construction steps increases.
[0004]
In the method (2), cement concrete and cement mortar have a slight water permeability, and thus a solidified mixture of the cement and the ground is also slightly water permeable. Therefore, harmful substances such as heavy metals contained in the consolidated body gradually re-elute into the soil according to the water permeability coefficient. In addition, the method (3) has a problem that the effect cannot be expected unless it is applied to sufficiently permeable ground. Therefore, when there are many soils with poor air permeability like in Japan, it is necessary to conduct a ground survey in advance and confirm the air permeability.
[0005]
Furthermore, in the method (4), even if a toxic substance such as heavy metal is insolubilized with a chelating agent, the toxic substance may diffuse due to the movement of groundwater in the insolubilized state. In addition, the chelating agent is decomposed by the action of microorganisms, which may cause reopening of harmful substances such as heavy metals and penetration into groundwater. Similarly, even when hexavalent chromium is reduced using a reducing agent, the reduced substance diffuses over a wide area, particularly in areas where the ground is weak (ie, where waterstop is poor and strength is insufficient). There is a risk that the material will flow into the groundwater.
[0006]
An object of the present invention is to provide a ground improvement method in which harmful substances such as heavy metals are insolubilized and immobilized, and are less likely to be re-eluted or reopened into the soil.
Furthermore, the other object of this invention is to provide the ground improvement construction method which can produce | generate the improvement body which can be used for a foundation pile etc., capturing and fixing harmful substances, such as a heavy metal.
[0007]
[Means for Solving the Problems]
The object of the present invention is to rotate the hardener injection rod while inserting it to a predetermined depth of the ground, and then gradually pull it back, and at least substantially hardener is sprayed from the front end of the hardener injection rod to obtain a substantially predetermined A ground improvement construction method for creating an improved body having a diameter in the ground, wherein a chelating agent is jetted from substantially the tip of the injection rod at least one of insertion and withdrawal of the injection rod. Achieved by improved construction method. According to the present invention, the hardener and the chelating agent are injected into the soil when the improved body containing the hardener is created. Therefore, harmful substances such as heavy metals contained in a predetermined region in the soil, that is, in the region where the improved body is created, are chelated and insolubilized by the chelating agent. Furthermore, this harmful substance is solidified by the hardener. Therefore, even if the hardened material such as cement has water permeability, since harmful substances are insolubilized, it is possible to significantly reduce the possibility of re-elution into the soil outside the improved body. Moreover, since it is solidified by the hardener, it is possible to remarkably reduce the risk of toxic substances spreading even in soils that have poor waterstop and insufficient strength.
[0008]
Moreover, according to this invention, since the improved body can be formed while insolubilizing and solidifying harmful substances in the soil, the civil engineering foundation construction process can be simplified. That is, this improved body can be used as a foundation pile.
[0009]
In a preferred embodiment of the present invention, when the hardener injection rod is pulled back from the ground, at least a mixture of the hardener and the chelate is jetted from a nozzle formed on the side surface of the tip of the rod. This embodiment includes, for example, the CCP method and the JSG method. In the JSG method, when the mixture is jetted from the nozzle, compressed air is jetted from another nozzle formed in the vicinity thereof.
[0010]
In another preferred embodiment of the present invention, when excavating the ground with a bit for excavation disposed substantially at the tip of the hardened material injection rod and pulling the rod back from the ground, At least water and a chelating agent are jetted from the formed nozzle at an ultrahigh pressure, and at least a curing material is jetted from the nozzle formed on the lower side. This embodiment includes a column jet grouting method. Alternatively, when excavating the ground with a excavating bit disposed at substantially the tip of the hardener injection rod and pulling the rod back from the ground, at least water is supplied from a nozzle formed on the upper side of the tip. A mixture of at least a curing material and a chelating agent may be injected from a nozzle formed at an ultrahigh pressure and formed below the side surface. In these aspects, when water is injected, it is preferable that the compressed air is injected from another nozzle disposed on the upper side.
[0011]
In still another preferred embodiment of the present invention, when cutting the ground, water is sprayed from the nozzle formed on the side surface of the tip portion at an ultrahigh pressure to cut the surrounding soil, and the hardening material When the injection rod is pulled back from the ground, at least a mixture of the hardener and the chelate is jetted from the nozzle. That is, the present invention can also be applied to a method of spraying a hardener after softening a predetermined range of soil in advance by water cutting.
[0012]
In another embodiment of the present invention, when the ground improvement method is rotated and inserted to a predetermined depth of the ground by rotating the hardener injection rod, at least water and a nozzle formed on the tip side surface of the rod A mixture of chelating agents is sprayed at an ultra-high pressure to cut surrounding soil, and the injection rod is rotated while being gradually pulled back, and at least a hardener is jetted from substantially the tip of the hardener injection rod to obtain a predetermined amount. It is comprised so that the improvement body containing the hardening | curing material and chelating agent which have a diameter may be produced in the ground. In this embodiment, at the time of water cutting, harmful substances such as heavy metals contained in a predetermined range of soil are chelated and insolubilized in advance using water containing a chelating agent. Thereafter, when the improved body is formed, harmful substances such as chelated heavy metals are solidified using a curing material.
[0013]
In yet another embodiment of the present invention, after a spiral is formed on the outer periphery and a stirring shaft having a hardener discharge port and a stirring blade is rotated at the lower end thereof to penetrate and reach a predetermined depth In the ground improvement method in which at least one of the stirrer shaft is inserted and withdrawn, the stirrer shaft is rotated and pulled back, and at least one of the stirrer shaft is inserted and withdrawn in at least one of the stirrer shafts. A chelating agent is discharged from the lower end. This embodiment includes a so-called mechanical stirring method. Also in this embodiment, harmful substances such as heavy metals contained in a predetermined region stirred by a stirring blade in the soil, that is, in a region where an improved body is formed, are chelated by a chelating agent and insolubilized. . Furthermore, this harmful substance is solidified by the hardener. Moreover, since the improved body can be formed while insolubilizing and solidifying harmful substances in the soil, the civil engineering foundation construction process can be simplified. That is, this improved body can be used as a foundation pile. Furthermore, in the said embodiment, the mixture of a hardening | curing material and a chelating agent may be injected from the discharge port of a stirring shaft.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. FIG. 1 is a diagram showing an outline of an apparatus for carrying out the ground improvement method according to the first embodiment of the present invention. The ground improvement device 10 according to the first embodiment is an application of the present invention to the JSG method. More specifically, as shown in FIG. 1, the ground improvement device 10 includes a rod portion 12 and a boring machine 14. The rod portion 12 is disposed at the bottom, a blade pit for cutting soil, a monitor 16 having a nozzle for spraying water or a hardener as necessary, a rod 18 connected to the monitor 16 and the top portion. It consists of a swivel 20. The rod 18 and the monitor 16 have a double tube structure including a path for a hardener, water, and the like, and a path for compressed air. The former is connected through a swivel 20 and a switching valve 22 to a super high pressure pump 24 and a water pump 26 disposed in a water tank 27. On the other hand, the latter is connected to the compressor 28 via the swivel 20. The ultra-high pressure pump 24 is connected to a grout mixer 30 for kneading a hardener such as cement milk, and the rod portion 12 is supplied with the hardener supplied from the grout mixer 26 via the switching valve 22 and the swivel 20 at an ultrahigh pressure. Can be sent to.
[0015]
The grout mixer 30 is connected to a tank 32 containing a chelating agent and a water pump 34 disposed in the water tank 27 so that the chelating agent and water are supplied. The tank 32 is filled with a chelating agent. In the present embodiment, a metal salt of dithiocarbamic acid (sodium salt or calcium salt) having a structure shown in Chemical Formula 1 is used as a chelating agent, but it is not limited to an organic chelating agent, For example, hydrogen sulfide (H ₂ S), sodium hydrosulfide (NaHS), sodium sulfide (Na ₂ Sulfur compounds such as S) and tripotassium phosphate (K) ₃ PO ₄ ), Sodium hypophosphite (NaH) ₂ PO ₂ ) And other inorganic chelating agents such as phosphates may be used.
[Chemical 1]

[0016]
In the ground improvement device configured as described above, first, the water pump 26 and the swivel 20 are communicated by the switching valve 22. Next, while jetting water downward from the lowermost nozzle of the monitor 16, the boring machine 14 rotates the rod portion 12 and inserts it into the ground.
[0017]
After the rod part 12 is advanced to a predetermined position in the ground, the super high pressure pump 24 and the swivel 20 are communicated by the switching valve 22. Next, also in the monitor 16, after switching the valve (not shown) so that the hardened material or the like can be injected from the nozzle (not shown) formed on the side wall, the boring machine 14 rotates the rod portion 12. While pulling out this. Since the water and the chelating agent are supplied to the cloud mixer 30, the mixture of the curing agent, the chelating agent and the water is sent from the ultrahigh pressure pump 24, and is connected to the side of the monitor 16 via the switching valve 22 and the swivel 20. From the nozzle formed in the above, the mixture becomes, for example, 200 kgf / cm ² It is injected at a very high pressure. On the other hand, the compressed air is also sent from the compressor 28, and this is sent via the swivel 20 from the second nozzle arranged in the vicinity of the nozzle, for example, 7 kgf / cm. ² Injected at a moderate pressure.
As the rod portion 12 is pulled out, a ground improvement body made of a mixture (see reference numeral 40 in FIG. 1) is formed in a region where the compressed air and the mixture are injected, and the rod and the soil are formed by the compressed air. The soil in the region is discharged to the ground through the gap.
[0018]
In the present embodiment, since the above mixture contains a chelating agent, heavy metals present in this region are chelated and insolubilized. Furthermore, since an improved body made of a hardener such as cement milk is created in the region, the insolubilized heavy metal is solidified. Therefore, according to the present embodiment, even if the hardening material such as cement has water permeability, harmful substances are insolubilized, so that the possibility of re-elution in the soil outside the improved body can be significantly reduced. In addition, since the harmful substance is solidified, it is possible to significantly reduce the risk of the harmful substance spreading. That is, according to the present embodiment, it is possible to remarkably reduce the risk of heavy metals re-eluting or reopening in the soil.
Moreover, according to this embodiment, since the chelating agent is also included in the soil discharged to the ground, it becomes possible to chelate heavy metals contained in the soil and insolubilize them. Therefore, it becomes possible to suppress the elution of harmful heavy metals from the soil, drainage, or improved body below the drainage standard or water quality standard. Furthermore, the ground improvement body which chelated the heavy metal in this way, insolubilized, and solidified the area | region containing such a heavy metal with the hardening | curing material can be used for a foundation pile etc.
[0019]
Next, the ground improvement method according to the second embodiment will be described. FIG. 2 is a diagram showing an outline of an apparatus for carrying out this construction method. The ground improvement device 100 according to the second embodiment is an application of the present invention to a column jet grouting method. In FIG. 2, the same components as those shown in FIG. As shown in FIG. 2, the apparatus 100 includes a rod portion 112 and a column machine 114. In the column jet grouting method, the rod portion 12 is suspended by a truck crane (not shown). The rod part 112 is arrange | positioned at the lowest part and has a nozzle which injects water, compressed air, and a hardening material, respectively. More specifically, a nozzle for injecting a curing material is disposed at the bottom, and nozzles for injecting water and compressed air are disposed at the top. The monitor 116 and the rod 118 have a triple tube structure including a path for a hardener, a path for water, and a path for compressed air. The path of the hardener is connected to the grout mixer 30 via the swivel 120 and the grout pump 36. The water path is connected to the grout mixer 26 via the swivel 120 and the ultra high pressure pump 24, and the compressed air path is connected to the compressor 28 via the swivel 120.
[0020]
As in the first embodiment, the grout mixer 30 is connected to a tank 32 containing a chelating agent and a water pump 34 so that the chelating agent and water are supplied.
In the ground improvement device thus configured, first, a guide pipe 122 is formed by embedding a casing pipe (not shown) using a boring device. Next, the rod portion 112 was inserted into the guide hole 122, and the rod portion 112 was rotated by the column machine 114 and pulled out, while being supplied from the nozzle located on the upper side via the ultrahigh pressure pump 24 and the swivel 120. For example, 400kgf / cm ² Of high pressure water and supplied through the compressor 28 and swivel 120, for example 7 kgf / cm ² Of compressed air is injected. Thereby, the soil of a predetermined area | region is cut. Further, the soil cut by the compressed air is discharged to the ground through the guide hole 122. On the other hand, the mixture of the curing agent, the chelating agent and water is, for example, 20 kgf / cm from the nozzle at the lower end via the grout pump 36 and the swivel 120. ² It is injected with the pressure of. Thereby, the improvement body containing a hardening | curing material and a chelating agent can be created in the area | region cut with the water and compressed air from an upper nozzle. Thus, as the rod portion 112 is pulled out, an improved body (see reference numeral 140 in FIG. 2) made of a mixture is formed in the region.
[0021]
Also in the second embodiment, since the mixture contains a chelating agent, the heavy metal present in this region is chelated to be insolubilized and solidified in the improved body. Therefore, according to the present embodiment, it is possible to remarkably reduce the risk of heavy metals re-eluting or reopening in the soil.
In particular, according to this embodiment, it is possible to insolubilize heavy metals in the mud liquid of the hardened material-mixed earth and sand that is generated when the hardened material is replaced and mixed with the earth and sand in the region to be filled with the hardened material, and By curing the hardener in the ground, it is possible to reduce the elution rate of heavy metals in the ground into the groundwater.
[0022]
Next, the ground improvement method according to the third embodiment of the present invention will be described. Also in this embodiment, the ground improvement device 200 applies the present invention to the column jet grouting method. The difference from the second embodiment is that a chelating agent is mixed with water used for cutting. Therefore, as shown in FIG. 3, in the ground improvement device 200 according to the third embodiment, the chelate tank 32 is connected to a mixer 202 that mixes the water supplied from the water pump 26 and the chelating agent. ing. Therefore, in this embodiment, the mixture of the water and the chelating agent supplied from the nozzle 202 on the upper side of the rod monitor 16 via the mixer 202, the ultrahigh pressure pump 24 and the swivel 120, and the compressor 28 and the swivel. The compressed air supplied through 120 is respectively jetted, whereby the soil in a predetermined area is cut. In this embodiment, water containing a chelating agent for soil cutting is supplied from one of the nozzles, for example, 4000 kgf / cm. ² Will be jetted.
[0023]
According to this embodiment, since water containing a chelating agent is used for cutting, heavy metals contained in the soil cut and discharged to the ground by compressed air can also be chelated by the chelating agent. It becomes possible. In particular, according to this embodiment, insolubilization of heavy metals contained in the sludge drainage of hardened material-mixed earth and sand generated when creating a region to be filled with hardened material, that is, when cutting the soil, and It becomes possible to insolubilize heavy metals in the ground and groundwater. In addition, it is possible to insolubilize heavy metals contained in the sludge liquid of the hardened material mixed earth and sand at the time of the hardener injection, and by hardening the hardened material in the ground, the elution rate of heavy metals in the ground to the groundwater Can be reduced.
[0024]
Next, the ground improvement method according to the fourth embodiment of the present invention will be described. In this embodiment, by so-called water cutting, ultrahigh pressure water is sprayed onto the region where the improved body is to be formed, and then the curing material is sprayed when the rod portion is pulled up. As shown in FIG. 4, the difference between the ground improvement device 300 according to this embodiment and the ground improvement device 10 according to the first embodiment is that the chelating agent supplied from the chelate tank 32 and the water pump 26. A mixer 302 that mixes water supplied from the mixer 302 is provided, and the switching valve 22 is arranged so that either the mixer 302 or the grout mixer 30 communicates with the ultrahigh pressure pump 24.
[0025]
In the ground improvement device 300 configured as described above, the mixer 302 and the ultrahigh pressure pump 24 communicate with each other by the switching valve 22 when the rod portion 12 is inserted, that is, when cutting. The rod portion 12 is inserted into the ground while being rotated by the boring machine 14, and a mixture of water and a chelating agent is, for example, 4000 kgf / cm from a nozzle formed on the side wall of the monitor 16. ² Compressed air that is injected at an ultrahigh pressure and supplied from the compressor 28 is, for example, 7 kgf / cm. ² It is injected with the pressure of. As a result, the soil in a predetermined region (see reference numeral 304 in FIG. 4A) becomes soft, and the heavy metal in the region is chelated. After the rod portion 12 is advanced to a predetermined position in the ground, the grout mixer 30 and the ultrahigh pressure pump 24 are communicated by the switching valve 22, and then the boring machine 14 pulls it out while rotating the rod portion 12. At this time, a mixture of water and a hardener is injected from the nozzle on the side wall of the monitor 16 at a high pressure, and compressed air is injected at a predetermined pressure. Therefore, as shown in FIG. 4B, an improved body including a hardener can be formed in the predetermined region 340. In addition, the soil softened by water cutting is pushed out toward the ground and discharged by compressed air and according to the creation of the improved body. In this embodiment, at the time of water cutting, first, heavy metal in a predetermined region is chelated using water containing a chelating agent, insolubilized, and then solidified by a hardener. A part of the chelated heavy metal is discharged to the ground.
[0026]
In particular, according to this embodiment, it is possible to insolubilize heavy metals in the sediment discharge mud that is generated when the region to be filled with the hardener is formed, that is, when water cutting is performed. In addition, it is possible to insolubilize heavy metals contained in the sludge liquid of the hardened material mixed earth and sand at the time of the hardener injection, and by hardening the hardened material in the ground, the elution rate of heavy metals in the ground to the groundwater Can be reduced.
[0027]
Next, the ground improvement method according to the fifth embodiment of the present invention will be described. Also in this embodiment, water cutting is used. As shown in FIG. 5, the ground improvement device 400 according to this embodiment is configured such that a chelating agent is supplied from the chelate tank 32 to the grout mixer 30 with the ground improvement device 300 according to the fourth embodiment. Therefore, it is different in that the mixer 302 is omitted. In the ground improvement device 400 according to this embodiment, when the rod portion 12 is inserted, that is, at the time of cutting, the water pump 26 and the ultrahigh pressure pump 24 are communicated by the switching valve 22, so that the nozzle formed on the side wall of the monitor 16. Thus, water is injected at an ultra-high pressure, and high-pressure air supplied from a compressor is injected at a predetermined pressure. Thereby, the soil of a predetermined area | region (refer code | symbol 404 of Fig.5 (a)) becomes soft. After the rod portion 12 is advanced to a predetermined position in the ground, the grout mixer 30 and the ultrahigh pressure pump 24 are communicated by the switching valve 22, and then the boring machine 14 pulls it out while rotating the rod portion 12. At this time, a mixture of water, a hardener, and a chelating agent is injected from a nozzle on the side wall of the monitor 16 at a high pressure, and compressed air is injected at a predetermined pressure. Therefore, as shown in FIG. 4B, the heavy metal contained in the predetermined region 340 is chelated by the chelating agent and solidified by the curing material. In this way, an improved body can be created in a predetermined region.
[0028]
The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the invention described in the claims, and these are also included in the scope of the present invention. Needless to say.
For example, in the above-described embodiment, the present invention is applied to a so-called jet grout method. However, the present invention is not limited to this, and it goes without saying that the present invention can also be applied to a mechanical stirring method. For example, a spiral is formed on the outer periphery, and the lower end part is inserted by rotating a stirring shaft provided with two sets of upper and lower hardener discharge ports and a stirring blade, and penetrates to a predetermined depth. To do. Next, the mixture of the curing agent and the chelating agent is discharged from the lower discharge port to treat the tip, and then the mixture is discharged from the upper discharge port while rotating and pulling out the stirring blade. What is necessary is just to build an improved body in a predetermined range. Alternatively, it goes without saying that the hardener chelating agent may be discharged from at least one of the upper and lower discharge ports when the stirring shaft is rotated and penetrated.
[0029]
Moreover, in the said embodiment, although this invention was applied to the JSG method and the column jet grouting method among jet grouting methods, this invention is applied also to other jet grouting methods, for example, a CCP method and 3S-MAN method. It is clear that it can be applied.
[0030]
Further, in the above embodiment, the chelating agent solution is accommodated in the chelating tank and supplied to the mixer or the like. However, the present invention is not limited to this. You may mix with the mixture (slurry) etc. of water and water.
[0031]
Moreover, in the said 4th Embodiment, although water cutting was made with the mixture of water and a chelating agent, and compressed air, it is not limited to this, Only by the mixture of water and a chelating agent Water cutting may be performed. Moreover, in the said 5th Embodiment, although water cutting was made with water and compressed air, you may make water cutting only with water.
Further, in the present specification, the function of one member may be realized by two or more physical members, or the function of two or more members may be realized by one physical member.
[0032]
【The invention's effect】
ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the ground improvement construction method which insolubilizes harmful substances, such as a heavy metal, and fix | immobilizes this, and has little possibility of being re-eluting in soil or being reopened. Moreover, according to this invention, it becomes possible to provide the ground improvement construction method which can produce | generate the improvement body which can be used for a foundation pile etc., capturing and fixing harmful substances, such as a heavy metal.
[Brief description of the drawings]
FIG. 1 is a diagram showing an outline of an apparatus for carrying out a ground improvement method according to a first embodiment of the present invention.
FIG. 2 is a diagram showing an outline of an apparatus for carrying out a ground improvement method according to a second embodiment of the present invention.
FIG. 3 is a diagram showing an outline of an apparatus for carrying out a ground improvement method according to a third embodiment of the present invention.
FIG. 4 is a diagram showing an outline of an apparatus for carrying out a ground improvement method according to a fourth embodiment of the present invention.
FIG. 5 is a diagram showing an outline of an apparatus for carrying out a ground improvement method according to a fifth embodiment of the present invention.
[Explanation of symbols]
10 Ground improvement device
12 Rod part
14 Boring machine
16 Monitor
18 rod
20 swivel
22 Switching valve
24 Super high pressure pump
26, 34 Water pump
28 Compressor
30 grout mixer
32 Chelating tank

Claims (9)

While rotating the hardener injection rod, insert it to a predetermined depth in the ground containing soil containing water-soluble harmful substances, and then gradually pull it back and spray at least the hardener from the approximate tip of the hardener injection rod. A ground improvement method for creating an improved body having a substantially predetermined diameter in the ground,
A ground improvement method comprising injecting a chelating agent from substantially the tip of the injection rod to insolubilize the toxic substance of the water-soluble substance at least when inserting or retracting the injection rod.   2. The ground improvement method according to claim 1, wherein when the hardener injection rod is pulled back from the ground, at least a mixture of the hardener and the chelate is sprayed from a nozzle formed on a side surface of the tip of the rod.   When excavating the ground with a excavating bit arranged at substantially the tip of the hardener injection rod and pulling the rod back from the ground, at least water and a chelating agent are formed from a nozzle formed on the upper side of the tip portion. The ground improvement construction method according to claim 1, wherein at least a hardening material is injected from a nozzle formed on the lower side.   When excavating the ground with a bit for excavation arranged substantially at the tip of the hardener injection rod, and pulling the rod back from the ground, at least water is super-high pressure from a nozzle formed on the upper side of the tip. The ground improvement method according to claim 1, wherein at least a mixture of a curing material and a chelating agent is injected from a nozzle formed at a lower side of the side surface.   Furthermore, when injecting water, compressed air is injected from the other nozzle arrange | positioned above, The ground improvement construction method of Claim 3 or 4 characterized by the above-mentioned.   At the time of cutting the ground, from the nozzle formed on the side surface of the tip portion, water is sprayed at an ultrahigh pressure to cut the surrounding soil, and at least when the hardener injection rod is pulled back from the ground, it is cured. The ground improvement method according to claim 1, wherein a mixture of the material and the chelate is sprayed from the nozzle.   When rotating the hardener injection rod and inserting it to a predetermined depth in the ground, at least a mixture of water and a chelating agent is sprayed from the nozzle formed on the side surface of the tip of the rod at an ultrahigh pressure to surround the surrounding soil. And then gradually pulling it back while rotating the injection rod, and spraying at least the hardening material from substantially the tip of the hardening material injection rod to provide an improved body containing a hardening material and a chelating agent having a substantially predetermined diameter. The ground improvement construction method according to claim 1, wherein the ground improvement construction method is formed inside. A spiral was formed on the outer periphery, and a stirring shaft having a hardener discharge port and a stirring blade was rotated at the lower end thereof to penetrate and reached a predetermined depth in the ground containing soil containing harmful substances of water-soluble substances. Later, while rotating the stirring shaft and pulling back, it is a ground improvement construction method for creating an improved body in the ground by discharging at least the hardener from the discharge port,
A ground improvement method characterized in that a chelating agent is discharged from the lower end portion to insolubilize the harmful substance of the water-soluble substance at least at the time of inserting and pulling back the stirring shaft.   The ground improvement method according to claim 8, wherein a mixture of the hardener and a chelating agent is jetted from the discharge port.

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