JP6238352B2 - Method for producing earth material that is easy to compact, embankment building method and soil backfilling method - Google Patents

Method for producing earth material that is easy to compact, embankment building method and soil backfilling method Download PDF

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JP6238352B2
JP6238352B2 JP2014009105A JP2014009105A JP6238352B2 JP 6238352 B2 JP6238352 B2 JP 6238352B2 JP 2014009105 A JP2014009105 A JP 2014009105A JP 2014009105 A JP2014009105 A JP 2014009105A JP 6238352 B2 JP6238352 B2 JP 6238352B2
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熊谷 隆宏
隆宏 熊谷
将真 高
将真 高
哲平 秋本
哲平 秋本
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Penta Ocean Construction Co Ltd
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本発明は、締め固め容易な土材料を作製する方法、並びにこの土材料を用いた盛土築造方法及び土埋戻し方法に関する。   The present invention relates to a method for producing an easily compacted soil material, and a method for constructing and embedding a soil using this soil material.

従来、土地造成や鉄道、道路、河川堤防、ダムなどの工事では、在来の地盤の上に土砂や岩石などの材料を盛り上げる盛土工が実施されている。かかる盛土は、充分に締め固めることが重要である。   Conventionally, in the construction of land, railways, roads, river dikes, dams, etc., embankment work has been carried out to raise materials such as earth and sand and rocks on the conventional ground. It is important that such embankments be fully compacted.

特許文献1は、廃ガラスを破砕して形成した粒度分類が礫質砂のガラス造粒砂とこれよりも粒度の小さい天然の山砂などの砂質材料とを混合した締め固め性に優れた路盤・路床用または盛土用混合材料を開示する。   In Patent Document 1, the particle size classification formed by crushing waste glass is excellent in compaction by mixing a glass granulated sand of gravel sand and a sandy material such as natural mountain sand having a smaller particle size than this. Disclosed are mixed materials for roadbeds, roadbeds or embankments.

特許文献2は、掘削土に、建設廃棄物のコンクリート塊またはアスファルト塊あるいはコンクリート塊とアスファルト塊の混合物を加えて破砕して、これに生石灰を加えてふるいにかけその粒径が40mm〜20mmのものと、その粒径が20mm〜2.5mmのものと、その粒径が2.5mm〜0mmのものにふるい分けてこれを所定の比率で混合した後、水を噴射し含水率を調整することにより上層路盤材に再生するようにした上層路盤材の製造方法を開示する。   According to Patent Document 2, a concrete lump or asphalt lump of construction waste or a mixture of concrete lump and asphalt lump is added to excavated soil and crushed, and quick lime is added to this and sieved, and the particle size is 40 mm to 20 mm. And, after sieving into particles having a particle size of 20 mm to 2.5 mm and particles having a particle size of 2.5 mm to 0 mm and mixing them at a predetermined ratio, water is injected to adjust the water content. Disclosed is a method for producing an upper layer roadbed material that is regenerated into an upper layer roadbed material.

特開2006-97349号公報JP 2006-97349 特開2002-363904号公報JP 2002-363904 A

特許文献1,2のように、盛土材料や路盤材を得るために材料を破砕して粒度調整する方法や細粒分を加えて粒度調整する方法が提案されている。しかしながら、材料を破砕する工程を含む場合、その破砕のために大型機械や設備が必要となり、コストが増加してしまうという問題がある。また、細粒分を加える場合、新たに材料を調達することが必要になり、コストが増加してしまうという問題がある。   As disclosed in Patent Documents 1 and 2, a method of crushing the material to adjust the particle size and a method of adjusting the particle size by adding fine particles have been proposed in order to obtain embankment material and roadbed material. However, when the process of crushing the material is included, there is a problem that a large machine or equipment is required for the crushing, and the cost increases. Moreover, when adding a fine grain part, it becomes necessary to procure a new material, and there exists a problem that cost will increase.

本発明は、上述のような従来技術の問題に鑑み、破砕工程を経ることなく、また、元々の使用する材料に対し新たな材料を用意することなく、締め固めが容易な土材料を得ることのできる締め固め容易な土材料の作製方法、並びにこの作製した土材料を用いた盛土築造方法及び土埋戻し方法を提供することを目的とする。   In view of the above-mentioned problems of the prior art, the present invention provides a soil material that can be compacted easily without going through a crushing step and without preparing a new material for the original material. An object of the present invention is to provide a method for producing a soil material that can be easily compacted, and a method for constructing and embedding a soil using the produced soil material.

上記目的を達成するために、本実施形態による締め固め容易な土材料の作製方法は、対象とする土材料の粒度試験を実施し粒径加積曲線を作成し、前記対象とする土材料が前記粒径加積曲線に基づいて締まりやすい土材料であるか否かを判断し、前記対象とする土材料が締まりやすい土材料でないと判断された場合、前記粒径加積曲線から求めた通過質量百分率50%のときの中央粒径D50よりも小さい粒径の範囲において全体に対する質量割合で10〜30%を占めかつ前記中央粒径D50に近い粒径の範囲を前記粒径加積曲線に基づいて設定し、前記対象とする土材料から前記設定した粒径の範囲内の成分を除去することで締め固め容易な土材料を作製することを特徴とする。ただし、前記対象とする土材料から単一粒径の土材料は除かれる。
In order to achieve the above object, a method for producing a compacted soil material according to the present embodiment performs a grain size test of a target soil material, creates a particle size accumulation curve, and the target soil material is It is determined whether or not the soil material is easy to tighten based on the particle size accumulation curve, and when it is determined that the target soil material is not a soil material easy to tighten, the passage determined from the particle size accumulation curve In the range of the particle size smaller than the median particle size D50 when the mass percentage is 50%, the range of the particle size that occupies 10-30% by mass with respect to the whole and is close to the median particle size D50 is the particle size accumulation curve. A soil material that is easy to compact is prepared by removing the components in the range of the set particle diameter from the target soil material. However, the soil material having a single particle diameter is excluded from the target soil material.

この締め固め容易な土材料の作製方法によれば、中央粒径D50よりも小さい粒径の範囲において全体に対する質量割合で10〜30%を占めかつ中央粒径D50に近い粒径の範囲を粒径加積曲線に基づいて設定し、かかる粒径の範囲内の成分を対象とする土材料から除去することで、破砕工程を経ることなく、また、元々の使用する材料に対し新たな材料を用意することなく、その土材料を締め固め容易な土材料にすることができる。 According to this method for producing a soil material that is easy to compact, in the range of the particle size smaller than the median particle size D 50 , the range of the particle size that occupies 10-30% by mass with respect to the whole and is close to the median particle size D 50 Is set based on the particle size accumulation curve, and components within the range of the particle size are removed from the target soil material, so that a new crushing process can be performed without passing through the crushing process. Without preparing the material, the soil material can be easily compacted into an earth material.

前記対象の土材料が式(1)を満たさない場合、締まりやすい土材料でないと判断することができる。日本統一土質分類法には、粒度のよい砂・礫(締まりやすい砂・礫)として式(1)を満たすことが提示されている。
1<Uc'≦√Uc (1)
ただし、Uc:均等係数(=D60/D10)
D60:前記粒径加積曲線において通過質量百分率60%のときの粒径
D10:前記粒径加積曲線において通過質量百分率10%のときの粒径
Uc':曲率係数(=(D30)2/(D60×D10))
D30:前記粒径加積曲線において通過質量百分率30%のときの粒径
When the target soil material does not satisfy the formula (1), it can be determined that the soil material is not easily tightened . The Japanese unified soil classification method is proposed to satisfy the formula (1) as sand and gravel with good grain size (sand and gravel that are easy to tighten).
1 <Uc '≦ √Uc (1)
However, Uc: Equal coefficient (= D60 / D10)
D60: particle diameter when the passing mass percentage of 60% in the cumulative volume size curve
D10: particle diameter when the passing mass percentage of 10% in the cumulative volume size curve
Uc ': Curvature coefficient (= (D30) 2 / (D60 × D10))
D30: particle diameter when the passing mass percentage of 30% in the cumulative volume size curve

上記締め固め容易な土材料の作製方法において、前記対象とする土材料を、前記設定された粒径の範囲の上限よりも一段階大きいふるいを上段に備えるとともに前記設定された粒径の範囲の下限よりも一段階小さいふるいを下段に備えるふるい装置にかけ、前記上段のふるいを通過し前記下段のふるいに留まる土粒子を除去することで、前記設定した粒径の範囲内の成分を除去するようにできる。   In the above-mentioned method for producing a soil material that is easy to compact, the target soil material is provided with a sieve that is one step larger than the upper limit of the set particle size range in the upper stage, and is within the set particle size range. A sieve smaller than the lower limit is passed through a sieve device provided at the lower stage, and the soil particles that pass through the upper sieve and remain on the lower sieve are removed, so that components within the set particle diameter range are removed. Can be.

また、前記除去された成分の土材料を、前記対象とする元の土材料に全体に対する質量割合で30〜40%の範囲になるように調整して加えて混合することが好ましい。かかる混合した土材料は締め固め容易である。これにより、除去された成分の土材料を利用することができ、廃棄する土の発生を極力抑えることができる   Moreover, it is preferable to adjust and add the removed soil material of the component to the original soil material as a target so that the mass ratio with respect to the whole is in a range of 30 to 40%. Such a mixed earth material is easy to compact. As a result, the soil material of the removed component can be used, and generation of soil to be discarded can be suppressed as much as possible.

また、対象の土材料が粒度試験の結果から上記式(1)を満たさない場合、前記対象の土材料を、式(1)を満たすように上述の作製方法により改良することができる。   Further, when the target soil material does not satisfy the above formula (1) from the result of the particle size test, the target soil material can be improved by the above-described production method so as to satisfy the formula (1).

本実施形態による盛土築造方法は、盛土を築造する方法であって、上述の作製方法によって締め固め容易な土材料に改良し、前記改良した土材料により盛土の築造を行うことを特徴とする。   The embankment construction method according to the present embodiment is a method for constructing embankment, characterized in that the embankment is improved by the above-described production method, and the embankment is constructed by the improved earth material.

この盛土築造方法によれば、土材料を締め固め容易な土材料に改良することができるので、かかる改良された土材料を用いることで盛土をよく締め固めて築造することができる。   According to this embankment construction method, the earth material can be compacted and improved to an easy earth material. Therefore, the embankment can be well compacted and constructed by using the improved earth material.

本実施形態による土埋戻し方法は、掘削した土を原位置に埋め戻す方法であって、前記掘削した土を上述の作製方法によって締め固め容易な土材料に改良し、前記改良した土材料を埋め戻すことを特徴とする。   The soil backfilling method according to the present embodiment is a method for backfilling the excavated soil to the original position, and the excavated soil is improved to an easily compacted soil material by the above-described manufacturing method, and the improved soil material is used. It is characterized by backfilling.

この土埋戻し方法によれば、掘削した土を締め固め容易な土材料に改良することができるので、埋め戻す際に土をよく締め固めることができる。   According to this soil backfilling method, the excavated soil can be compacted and improved to an easy soil material, so that the soil can be compacted well during backfilling.

本発明によれば、破砕工程を経ることなく、また、元々の使用する材料に対し新たな材料を用意することなく、締め固めが容易な土材料を得ることのできる締め固め容易な土材料の作製方法、並びにこの作製した土材料を用いた盛土築造方法及び土埋戻し方法を提供することができる。   According to the present invention, it is possible to obtain an easily compacted earth material that can be easily compacted without going through a crushing step and without preparing a new material for the original material to be used. It is possible to provide a production method, a banking construction method and a soil backfilling method using the produced earth material.

本実施形態による締め固め容易な土材料の作製方法の各工程S01〜S07を説明するためのフローチャートである。It is a flowchart for demonstrating each process S01-S07 of the preparation method of the earth material easy to compact according to this embodiment. 図1の除去工程S05を実施可能な機械式振動ふるい装置の概略的な構成を示す図である。It is a figure which shows schematic structure of the mechanical vibration sieving apparatus which can implement removal process S05 of FIG. 実施例1の元の材料、方法(i)による土材料、および、方法(ii)による土材料についての粒度試験による粒径加積曲線を示すグラフである。It is a graph which shows the particle size accumulation curve by the particle size test about the original material of Example 1, the earth material by the method (i), and the earth material by the method (ii). 実施例1の粒度試験における各粒径について通過質量百分率のデータを示す表である。3 is a table showing data on a passing mass percentage for each particle size in the particle size test of Example 1. 実施例2の元の材料、方法(i)による土材料、および、方法(ii)による土材料についての粒度試験による粒径加積曲線を示すグラフである。It is a graph which shows the particle size accumulation curve by the particle size test about the original material of Example 2, the earth material by the method (i), and the earth material by the method (ii). 実施例2の粒度試験における各粒径について通過質量百分率のデータを示す表である。4 is a table showing data on the passing mass percentage for each particle size in the particle size test of Example 2. 比較例1(40%除去)、比較例2(5%除去)についての粒度試験による粒径加積曲線を示すグラフである。It is a graph which shows the particle size accumulation curve by the particle size test about Comparative Example 1 (40% removal) and Comparative Example 2 (5% removal). 比較例1,2の粒度試験における各粒径について通過質量百分率のデータを示す表である。It is a table | surface which shows the data of a passing mass percentage about each particle size in the particle size test of the comparative examples 1 and 2. FIG. 比較例3(5%除去)についての粒度試験による粒径加積曲線を示すグラフである。It is a graph which shows the particle size accumulation curve by the particle size test about the comparative example 3 (5% removal). 比較例3の粒度試験における各粒径について通過質量百分率のデータを示す表である。10 is a table showing data on a passing mass percentage for each particle size in a particle size test of Comparative Example 3. 比較例4(20%含有)、比較例5(50%含有)についての粒度試験による粒径加積曲線を示すグラフである。It is a graph which shows the particle size accumulation curve by the particle size test about Comparative Example 4 (20% containing) and Comparative Example 5 (50% containing). 比較例4,5の粒度試験における各粒径について通過質量百分率のデータを示す表である。It is a table | surface which shows the data of a passing mass percentage about each particle size in the particle size test of the comparative examples 4 and 5. FIG. 比較例6(20%含有)、比較例7(50%含有)についての粒度試験による粒径加積曲線を示すグラフである。It is a graph which shows the particle size accumulation curve by the particle size test about Comparative Example 6 (20% containing) and Comparative Example 7 (50% containing). 比較例6,7の粒度試験における各粒径について通過質量百分率のデータを示す表である。It is a table | surface which shows the data of a passing mass percentage about each particle size in the particle size test of the comparative examples 6 and 7. FIG.

以下、本発明を実施するための形態について図面を用いて説明する。図1は本実施形態による締め固め容易な土材料の作製方法の各工程S01〜S07を説明するためのフローチャートである。   Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. FIG. 1 is a flowchart for explaining the steps S01 to S07 of the method for producing an easily compacted earth material according to the present embodiment.

図1を参照して、本実施形態による締め固め容易な土材料の作製方法について説明する。まず、事前に対象とする土材料について粒度試験を実施する(S01)。次に、この粒度試験に基づいて対象とする土材料の粒径加積曲線を作成する(S02)。   With reference to FIG. 1, the manufacturing method of the earth material which is easy to compact by this embodiment is demonstrated. First, a particle size test is performed on the target soil material in advance (S01). Next, a particle size accumulation curve of the target soil material is created based on this particle size test (S02).

粒度試験は、たとえば、JIS規格「土の粒度試験方法」(JIS A 1204:2000)にしたがって行うことができる。ふるい分析は、呼び寸法が75mm、53mm、37.5mm、26.5mm、19mm、9.5mm、4.75mm、2mm、0.85mm、0.425mm、0.25mm、0.106mm、0.075mmである試験用鋼製ふるいを用いて行うことができる。   The particle size test can be performed, for example, according to the JIS standard “Soil Particle Size Test Method” (JIS A 1204: 2000). Sieve analysis uses test steel sieves with nominal dimensions of 75mm, 53mm, 37.5mm, 26.5mm, 19mm, 9.5mm, 4.75mm, 2mm, 0.85mm, 0.425mm, 0.25mm, 0.106mm, 0.075mm Can be done.

次に、作成した粒径加積曲線に基づいて対象の土材料がたとえば次式(1)を満たし締まりやすい土であるか否かを判断する(S03)。式(1)は日本統一土質分類法において提示され、式(1)を満たすと、粒度のよい砂・礫(締まりやすい砂・礫)と判断される。   Next, based on the created particle size accumulation curve, it is determined whether or not the target soil material satisfies the following formula (1), for example, and is easily soiled (S03). Formula (1) is presented in Japan's unified soil classification method, and if it satisfies Formula (1), it is judged that sand and gravel with good particle size (sand and gravel that are easy to tighten).

1<Uc'≦√Uc (1)
ただし、Uc:均等係数(=D60/D10
D60:粒径加積曲線において通過質量百分率60%のときの粒径
D10:粒径加積曲線において通過質量百分率10%のときの粒径
Uc':曲率係数(=(D302/(D60×D10))
D30:粒径加積曲線において通過質量百分率30%のときの粒径
1 <Uc '≦ √Uc (1)
However, Uc: uniformity coefficient (= D 60 / D 10)
D 60 : Particle size when the passing mass percentage is 60% in the particle size accumulation curve
D 10 : Particle size when the passing mass percentage is 10% in the particle size accumulation curve
Uc ': Curvature coefficient (= (D 30 ) 2 / (D 60 × D 10 ))
D 30 : Particle size when the passing mass percentage is 30% in the particle size accumulation curve

上記判断工程S03において対象の土材料が式(1)を満たさず締まりやすい土でないと判断された場合、対象の土材料から除去すべき粒径の範囲を設定する(S04)。すなわち、粒径加積曲線において通過質量百分率50%のときの粒径D50(中央粒径)よりも小さい粒径の範囲において全体に対する質量割合で10〜30%を占めかつ中央粒径D50に近い粒径の範囲を粒径加積曲線に基づいて設定し、除去すべき粒径の範囲とする。 If it is determined in the determination step S03 that the target soil material does not satisfy the formula (1) and is not easily tightened, a range of particle sizes to be removed from the target soil material is set (S04). That is, in the particle size accumulation curve, it accounts for 10 to 30% by mass with respect to the whole in a particle size range smaller than the particle size D 50 (median particle size) when the passing mass percentage is 50%, and the median particle size D 50 A particle size range close to is set based on the particle size accumulation curve, and is set as the particle size range to be removed.

たとえば、上記粒径加積曲線に基づいて、中央粒径D50よりも小さくかつ中央粒径D50に最も近い粒径D1が全体に対する質量割合で10〜30%を満たすか否かを判断し、その質量割合Xが10〜30%の範囲内にある場合、除去すべき粒径の範囲をD1と設定する。また、その質量割合Xが10%未満の場合、次に小さい粒径D2の全体に対する質量割合Yを求め、それらの質量割合の合計(X+Y)が10〜30%の範囲内にあれば、除去すべき粒径の範囲をD2〜D1と設定する。また、その質量割合Xが30%を超えた場合、次に小さい粒径D2の全体に対する質量割合Yを求め、その質量割合Yが10〜30%の範囲内にあれば、除去すべき粒径の範囲をD2と設定する。また、上記設定される粒径D1,D2とは、上記粒度試験における各粒径(ふるいの呼び寸法)であってよい。 For example, based on the grain size accumulation curve, nearest particle size D1 to and median particle diameter D 50 less than the median particle diameter D 50 determines whether meet 10-30% by mass percentage of the total When the mass ratio X is in the range of 10 to 30%, the range of the particle size to be removed is set as D1. Moreover, when the mass ratio X is less than 10%, the mass ratio Y with respect to the whole of the next smallest particle diameter D2 is obtained, and if the total (X + Y) of these mass ratios is within the range of 10 to 30%, it is removed. The range of the particle size to be set is set to D2 to D1. Further, when the mass ratio X exceeds 30%, the mass ratio Y to the whole of the next smallest particle diameter D2 is obtained, and if the mass ratio Y is within the range of 10 to 30%, the particle diameter to be removed Is set to D2. Further, the set particle sizes D1 and D2 may be the respective particle sizes (nominal size of the sieve) in the particle size test.

次に、対象の土材料から上記設定した粒径の範囲内の成分を、ふるいを使って除去する(S05)。この設定した粒径の範囲内の成分を除去した土材料は、上記式(1)を満たし、粒度のよい土であり、締まりやすい土である(方法(i))。   Next, components within the set particle size range are removed from the target soil material using a sieve (S05). The soil material from which the components within the set particle size range are removed satisfies the above formula (1), is a soil with good particle size, and is easy to tighten (method (i)).

たとえば、除去すべき粒径の範囲がD1と設定され、D1=0.25mmであるとすると、呼び寸法が0.425mmのふるい、および、0.106mmのふるいを用いて、対象の土材料を大きいふるい(0.425mm)にかけ、この大きいふるいを通過した土を、次に、小さいふるい(0.106mm)にかけ、この小さいふるいに残った土を除去する。   For example, if the range of the particle size to be removed is set to D1 and D1 = 0.25 mm, the target soil material is a large sieve using a sieve having a nominal size of 0.425 mm and a sieve having a size of 0.106 mm ( The soil that has passed through this large sieve is then passed through a small sieve (0.106 mm) to remove the remaining soil on this small sieve.

次に、上記除去された成分の土を元の土材料に混合する場合(S06)、除去された成分の土を上記対象とする元の土材料に全体に対する質量割合で30〜40%の範囲内になるように調整して加えてミキサ等により混合する(S07)。このようにして、混合された土材料は、上記式(1)を満たし、粒度のよい土であり、締まりやすい土である(方法(ii))。   Next, when the soil of the removed component is mixed with the original soil material (S06), the range of 30 to 40% by mass ratio of the removed soil of the component to the original soil material as a target Adjustment is made so as to be within, and mixing is performed by a mixer or the like (S07). Thus, the mixed soil material satisfies the above formula (1), is a soil with good particle size, and is a soil that is easy to tighten (method (ii)).

上述のように、本実施形態によれば、(i)上記設定した粒径の範囲内の成分を除去工程S05で除去する方法により得られた土材料A、および、(ii)除去工程S05で除去された成分の土を元の土材料に混合工程S07で所定範囲の割合で混合する方法により得られた土材料Bは、いずれも、上記式(1)を満たし、粒度のよい土であり、締まりやすい土である。このように、対象の土材料から締め固め容易な土材料を作製することができる。対象の土材料が締め固め容易な土材料でなくとも、破砕工程を経ることなく、また、元々の使用する材料に対し新たな材料を用意することなく、その土材料を締め固め容易な土材料に改良することができる。このため、かかる土材料の作製・改良にはコストがさほどかからない。   As described above, according to the present embodiment, (i) the soil material A obtained by the method of removing the components within the set particle diameter range in the removal step S05, and (ii) the removal step S05 The soil material B obtained by the method of mixing the removed component soil with the original soil material in the mixing step S07 at a ratio within a predetermined range all satisfies the above formula (1) and is a soil with good particle size. It is soil that is easy to tighten. In this way, an easily compacted soil material can be produced from the target soil material. Even if the target soil material is not an easily compacted soil material, it is easy to compact the soil material without going through the crushing process and preparing a new material for the original material. Can be improved. For this reason, it does not cost much to produce and improve such a soil material.

また、除去された成分の土を元の土材料に混合することにより、除去された成分の土材料を効率的に利用することができ、廃棄する土の発生を極力抑えることができる。このため、廃棄コスト低減の点で有利である。   Further, by mixing the soil of the removed component with the original soil material, the soil material of the removed component can be used efficiently, and generation of soil to be discarded can be suppressed as much as possible. For this reason, it is advantageous in terms of reducing the disposal cost.

上述の作製方法によって締め固め容易な土材料に改良し、その改良した土材料は、たとえば、土地造成や鉄道、道路、河川堤防、ダムなどの工事に適用される盛土工に利用することで、盛土をよく締め固めて築造することができる。   By improving the soil material to be easily compacted by the above-mentioned production method, the improved soil material can be used, for example, for land preparation, embankment work applied to construction of railways, roads, river dikes, dams, etc. The embankment can be compacted and built.

また、基礎工や埋設管敷設などのために掘削された地盤部分を工事終了後に埋める際に、その掘削した土を上述の作製方法によって締め固め容易な土材料に改良し、その改良した土材料を用いて埋めることで、土をよく締め固めることができる。また、その掘削した土を原位置に埋め戻すので、掘削した土を効率的に利用できる。   Also, when filling the ground excavated for foundation work or buried pipe laying after the completion of construction, the excavated soil is improved to an easily compacted soil material by the above-mentioned production method, and the improved soil material By filling with, the soil can be well compacted. Further, since the excavated soil is backfilled to the original position, the excavated soil can be used efficiently.

次に、図1の除去工程を実施するための機械式振動ふるい装置について図2を参照して説明する。図2は図1の除去工程S05を実施可能な機械式振動ふるい装置の概略的な構成を示す図である。   Next, a mechanical vibration sieving device for carrying out the removing step of FIG. 1 will be described with reference to FIG. FIG. 2 is a diagram showing a schematic configuration of a mechanical vibration sieving apparatus capable of performing the removing step S05 of FIG.

図2のように、機械式振動ふるい装置10は、振動部11aにより水平方向bに往復振動され、大きい(粗い)網のふるいから構成される第1のふるい部11と、振動部12aにより水平方向bに往復振動され、第1のふるい部11の下方に配置され、小さい(細かい)網のふるいから構成される第2のふるい部12と、を備える。振動部11a、12aは、モータや偏心カムなどを用いた公知の振動装置を使用できる。   As shown in FIG. 2, the mechanical vibration sieving device 10 is reciprocally vibrated in the horizontal direction b by the vibration part 11a, and is horizontal by the first screen part 11 composed of a large (coarse) mesh screen and the vibration part 12a. A second sieve portion 12 which is reciprocally oscillated in the direction b and is arranged below the first sieve portion 11 and which is composed of a small (fine) mesh sieve. As the vibration units 11a and 12a, a known vibration device using a motor, an eccentric cam, or the like can be used.

図2の機械式振動ふるい装置10によれば、貯留部(図示省略)等から供給された対象の土材料MをベルトコンベアBCにより方向aに搬送し、第1のふるい部11へ落下させ所定量を投入すると、その土材料Mは、第1のふるい部11で水平方向bに振動されることで、そのふるいを通過した粒径からなる土材料が第2のふるい部12へと落下し、その落下した土材料は、第2のふるい部12で水平方向bに振動されることで、そのふるいを通過した粒径からなる土材料が最下段の受け部BTへと落下する。   According to the mechanical vibration sieving device 10 of FIG. 2, the target soil material M supplied from a storage unit (not shown) or the like is conveyed in the direction a by the belt conveyor BC and dropped to the first sieving unit 11. When the fixed amount is input, the soil material M is vibrated in the horizontal direction b by the first sieve unit 11, so that the soil material having a particle size that has passed through the sieve falls to the second sieve unit 12. The fallen earth material is vibrated in the horizontal direction b by the second sieve portion 12 so that the earth material having a particle size that has passed through the sieve falls to the lowermost receiving portion BT.

たとえば、対象の土材料Mから除去すべき粒径の範囲が0.25mmと設定され、第1のふるい部11のふるいの呼び寸法を0.425mm、第2のふるい部12のふるいの呼び寸法を0.106mmとすると、上述のような第1,第2のふるい部11におけるふるい分けの結果、図2のように、第1のふるい部11には、そのふるい(0.425mm)を通過しなかった粒径からなる土材料M1が残り、第2のふるい部12には、第1のふるい部11のふるい(0.425mm)を通過したが、そのふるい(0.106mm)を通過しなかった粒径からなる土材料M2が残り、最下段の受け部BTには、両方のふるいを通過した粒径からなる土材料M3が貯まる。   For example, the range of the particle size to be removed from the target soil material M is set to 0.25 mm, the nominal size of the sieve of the first sieve unit 11 is 0.425 mm, and the nominal size of the sieve of the second sieve unit 12 is 0.106. Assuming that mm, as a result of sieving in the first and second sieving portions 11 as described above, the first sieving portion 11 has a particle diameter that has not passed through the sieving (0.425 mm) as shown in FIG. The soil material M1 consisting of the soil remains, and the second sieve portion 12 passes through the sieve (0.425 mm) of the first sieve portion 11 but does not pass through the sieve (0.106 mm). The material M2 remains, and the soil material M3 having a particle size that has passed through both sieves is stored in the lowermost receiving portion BT.

第1,第2のふるい部11,12を、たとえば、左右いずれか一方に傾斜させることで、残った土材料M1,M2を第1,第2のふるい部11,12から排出させる。土材料M1と土材料M3との混合材料が、対象の土材料Mから設定した粒径の範囲(0.25mm)の成分を方法(i)により除去した後の土材料Aである。   The first and second sieve portions 11 and 12 are inclined, for example, to the left or right side, and the remaining soil materials M1 and M2 are discharged from the first and second sieve portions 11 and 12, for example. The mixed material of the earth material M1 and the earth material M3 is the earth material A after the component of the particle size range (0.25 mm) set from the target earth material M is removed by the method (i).

また、設定した粒径の範囲(0.25mm)を除去した成分からなる土が土材料M2で、方法(ii)により土材料M2を元の土材料Mに全体に対する質量割合で30〜40%となるように計量し、ミキサなどを用いて混合した土が土材料Bである。   Moreover, the soil which consists of the component which remove | eliminated the range (0.25mm) of the set particle size is the earth material M2, and the earth material M2 is 30-40% by the mass ratio with respect to the whole earth material M by the method (ii). The soil material B is the soil that is so weighed and mixed using a mixer or the like.

図2の機械式振動ふるい装置10によれば、第1,第2のふるい部11,12などを所定の大きさにすることで、対象の土材料Mから方法(i)による土材料A、および、方法(ii)による土材料Bを所定量だけ効率的に作製することができる。   According to the mechanical vibration sieving device 10 of FIG. 2, by setting the first and second sieving portions 11, 12 and the like to a predetermined size, the soil material A by the method (i) from the target soil material M, And the earth material B by the method (ii) can be efficiently produced by a predetermined amount.

次に、本発明について実施例により具体的に説明するが、本発明は、本実施例に限定されるものではない。なお、本実施例では、土材料についてJIS A 1204:2000にしたがって粒度試験を行い、粒径加積曲線を作成した。この粒度試験では、ふるいの呼び寸法が75mm、53mm、37.5mm、26.5mm、19mm、9.5mm、4.75mm、2mm、0.85mm、0.425mm、0.25mm、0.106mm、0.075mmである試験用鋼製ふるいを用いた。   EXAMPLES Next, although an Example demonstrates this invention concretely, this invention is not limited to a present Example. In this example, the soil material was subjected to a particle size test in accordance with JIS A 1204: 2000 to create a particle size accumulation curve. In this particle size test, the nominal size of the sieve is 75mm, 53mm, 37.5mm, 26.5mm, 19mm, 9.5mm, 4.75mm, 2mm, 0.85mm, 0.425mm, 0.25mm, 0.106mm, 0.075mm A sieve was used.

[実施例1]
実施例1は、対象とする元の土材料が比較的均等係数が大きいが、曲率係数が小さい砂質土の場合である。図3に、実施例1の元の土材料について行った粒度試験から得た粒径加積曲線を示し、図4に、実施例1の元の材料の各粒径について通過質量百分率のデータを示す。図3、図4から均等係数Uc、および、曲率係数Uc'を求めると、Uc=6.29、Uc'=0.73であり、実施例1の元の土材料は式(1)を満足せず、粒度のよい土でなく、締まりやすい土ではないと判断される。
[Example 1]
Example 1 is a case where the target soil material is sandy soil having a relatively large uniformity coefficient but a small curvature coefficient. FIG. 3 shows the particle size accumulation curve obtained from the particle size test performed on the original soil material of Example 1, and FIG. 4 shows the data on the passing mass percentage for each particle size of the original material of Example 1. Show. When the uniformity coefficient Uc and the curvature coefficient Uc ′ are obtained from FIGS. 3 and 4, Uc = 6.29 and Uc ′ = 0.73, and the original soil material of Example 1 does not satisfy the formula (1), and the grain size It is judged that this soil is not good soil and is not easy to tighten.

実施例1の元の材料について図3、図4から中央粒径D50を求めると、0.31mmであり、粒径0.25mmが中央粒径D50よりも小さく、中央粒径D50に最も近く、全体に対する質量割合で23%を占めるため、除去すべき粒径の範囲を0.25mmとし、呼び寸法が0.425mm、および、0.106mmのふるいを用いて、ふるい分けをし、大きい寸法のふるい(0.425mm)を通過し、小さい寸法のふるい(0.106mm)に残った土を除去することで方法(i)による土材料を得た。この方法(i)による土材料について粒度試験を行い、その結果を図3、図4に示す。図3、図4から均等係数Uc=6.11、曲率係数Uc'=1.58が得られ、式(1)を満足し、元の土材料を、粒度のよい土、締まりやすい土に改良することができた。 Example 1 of the original for the material 3, when determining the median particle diameter D 50 of FIG. 4, a 0.31 mm, particle size 0.25mm is smaller than the median particle diameter D 50, closest to the median particle diameter D 50 Since the mass ratio is 23% with respect to the whole, the range of the particle size to be removed is set to 0.25 mm, and the sieve is screened using a sieve having a nominal size of 0.425 mm and 0.106 mm, and a large size sieve (0.425 The soil material obtained by the method (i) was obtained by removing the soil that passed through the small-size sieve (0.106 mm). A particle size test was performed on the soil material by this method (i), and the results are shown in FIGS. 3 and 4, the uniformity coefficient Uc = 6.11 and the curvature coefficient Uc '= 1.58 are obtained, satisfying equation (1), and the original soil material can be improved to a soil with good grain size and easy to tighten. It was.

次に、上記元の土材料に上記除去した土を全体に対する質量割合で35%になるように加えて混合することで方法(ii)による土材料を得た。この方法(ii)による土材料について粒度試験を行い、その結果を同じく図3、図4に示す。図3、図4から均等係数Uc=4.57、曲率係数Uc'=1.01が得られ、式(1)を満足し、元の土材料を、粒度のよい土、締まりやすい土に改良することができた。   Next, the removed soil was added to the original soil material at a mass ratio of 35% with respect to the total, and mixed to obtain a soil material by the method (ii). A particle size test was performed on the soil material by this method (ii), and the results are also shown in FIGS. 3 and 4, the uniformity coefficient Uc = 4.57 and the curvature coefficient Uc '= 1.01 are obtained, satisfying the equation (1), and the original soil material can be improved to a soil with good grain size and easy to tighten. It was.

[実施例2]
実施例2は、対象とする元の土材料が均等係数が小さく、単一粒径に近い場合である。図5に実施例2の元の材料、方法(i)による土材料、および、方法(ii)による土材料についての粒度試験による粒径加積曲線を示す。図6に、粒度試験における各粒径について通過質量百分率のデータを示す。図5、図6から元の土材料は、均等係数Uc=1.92、曲率係数Uc'=0.85であり、式(1)を満足せず、粒度のよい土でなく、締まりやすい土ではない。
[Example 2]
Example 2 is a case where the original soil material of interest has a small uniformity coefficient and is close to a single particle size. FIG. 5 shows the particle size accumulation curve by the particle size test for the original material of Example 2, the soil material by method (i), and the soil material by method (ii). FIG. 6 shows data on the passing mass percentage for each particle size in the particle size test. From FIG. 5 and FIG. 6, the original soil material has the uniformity coefficient Uc = 1.92 and the curvature coefficient Uc ′ = 0.85, does not satisfy the formula (1), is not a soil with good grain size, and is not a soil that is easy to tighten.

実施例2の元の土材料は、中央粒径D50が0.41mmであり、粒径0.25mmおよび粒径0.106mmの各成分の和が中央粒径D50よりも小さく全体に対する質量割合で11%を占めるため、除去すべき粒径の範囲を0.106mm〜0.25mmとし、ふるい目の呼び寸法が0.425mm、および、0.075mmのふるいを用いてふるい分けをし、大きい寸法のふるい(0.425mm)を通過し、小さいふるい目のふるい(0.075mm)に残った土を除去することで方法(i)による土材料を得た。この方法(i)による土材料は、図5,図6から均等係数Uc=3.33、曲率係数Uc'=1.63であり、式(1)を満足し、元の土材料を、粒度のよい土、締まりやすい土に改良することができた。 The original soil material of Example 2 has a median particle diameter D 50 of 0.41 mm, and the sum of the components of the particle diameters of 0.25 mm and 0.106 mm is smaller than the median particle diameter D 50 in a mass ratio of 11 to the whole. Therefore, the range of the particle size to be removed is set to 0.106mm to 0.25mm, and the sieve size is 0.425mm and 0.075mm. The soil material obtained by the method (i) was obtained by removing the soil remaining on the small sieve sieve (0.075 mm). The soil material by this method (i) has the uniformity coefficient Uc = 3.33 and the curvature coefficient Uc ′ = 1.63 from FIG. 5 and FIG. 6, satisfies the formula (1), and replaces the original soil material with a fine grained soil, It was possible to improve the soil to be easy to tighten.

次に、上記元の土材料に上記除去した土を全体に対する質量割合で35%になるように加えて混合することで方法(ii)による土材料を得た。この方法(ii)による土材料は、図5,図6から均等係数Uc=3.08、曲率係数Uc'=1.02が得られ、式(1)を満足し、元の土材料を、粒度のよい土、締まりやすい土に改良することができた。   Next, the removed soil was added to the original soil material at a mass ratio of 35% with respect to the total, and mixed to obtain a soil material by the method (ii). As for the soil material by this method (ii), the uniformity coefficient Uc = 3.08 and the curvature coefficient Uc ′ = 1.02 are obtained from FIG. 5 and FIG. It was possible to improve the soil to be easy to tighten.

[比較例1、2]
比較例1,2は、実施例1の元の材料を対象にした方法(i)に対し設定する粒径範囲を質量割合で40%、5%としたものである。比較例1として、実施例1の元の土材料について中央粒径D50(0.31mm)よりも小さく、中央粒径D50に最も近く、全体に対する質量割合で40%を占める粒径の範囲を設定し、この範囲の粒径成分を除去した。すなわち、ふるい(0.425mm)を通過し、ふるい(0.106mm)に残った土、および、ふるい(0.075mm)に残った土の一部を全体に対する質量割合で40%を占めるように除去した。
[Comparative Examples 1 and 2]
In Comparative Examples 1 and 2, the particle size range set for the method (i) targeting the original material of Example 1 is 40% and 5% by mass ratio. As Comparative Example 1, the range of the particle size that is smaller than the median particle size D 50 (0.31 mm) of the original soil material of Example 1 and that is closest to the median particle size D 50 and occupies 40% of the total mass ratio. The particle size component in this range was set and removed. That is, the soil that passed through the sieve (0.425 mm) and remained on the sieve (0.106 mm) and a part of the soil remaining on the sieve (0.075 mm) were removed so as to occupy 40% of the total mass.

比較例2として、実施例1の元の土材料についてふるい(0.106mm)に残った土の一部を全体に対する質量割合で5%を占めるように除去した。   As Comparative Example 2, a part of the soil remaining in the sieve (0.106 mm) of the original soil material of Example 1 was removed so as to occupy 5% in terms of mass ratio to the whole.

図7に、比較例1(40%除去)、比較例2(5%除去)についての粒度試験による粒径加積曲線を示す。実施例1の方法(i)による結果もあわせて示す。図8に、比較例1,2の粒度試験における各粒径について通過質量百分率のデータを示す。図7,図8から比較例1の土材料(40%除去)は、均等係数Uc=2.32、曲率係数Uc'=0.92であり、式(1)を満足せず、粒度のよい土でなく、締まりやすい土ではない。同様に、比較例2の土材料(5%除去)は、均等係数Uc=6.43、曲率係数Uc'=0.71であり、式(1)を満足せず、粒度のよい土でなく、締まりやすい土ではない。   In FIG. 7, the particle size accumulation curve by the particle size test about Comparative Example 1 (40% removal) and Comparative Example 2 (5% removal) is shown. The result by the method (i) of Example 1 is also shown. FIG. 8 shows the data of the passing mass percentage for each particle size in the particle size test of Comparative Examples 1 and 2. 7 and 8, the soil material of Comparative Example 1 (40% removal) has an equality coefficient Uc = 2.32 and a curvature coefficient Uc ′ = 0.92, does not satisfy the formula (1), is not a soil with good grain size, It's not easy to tighten. Similarly, the soil material of Comparative Example 2 (5% removal) has a uniformity coefficient Uc = 6.43 and a curvature coefficient Uc ′ = 0.71, does not satisfy the formula (1), is not a soil with good grain size, and is easily soiled. is not.

[比較例3]
比較例3は、実施例2の元の材料を対象にした方法(i)に対し設定する粒径範囲を質量割合で5%としたものである。比較例3として、実施例2の元の土材料(中央粒径D50=0.41mm)についてふるい(0.425mm)を通過し、ふるい(0.25mm)に残った土の一部を全体に対する質量割合で5%を占めるように除去した。
[Comparative Example 3]
In Comparative Example 3, the particle size range set for the method (i) targeting the original material of Example 2 is 5% by mass ratio. As Comparative Example 3, the original soil material of Example 2 (median particle size D 50 = 0.41 mm) passed through a sieve (0.425 mm), and a part of the soil remaining on the sieve (0.25 mm) was a mass ratio with respect to the whole Removed to account for 5%.

図9に、比較例3(5%除去)についての粒度試験による粒径加積曲線を示す。実施例2の方法(i)による結果もあわせて示す。図10に、比較例3の粒度試験における各粒径について通過質量百分率のデータを示す。図9,図10から比較例3の土材料(5%除去)は、均等係数Uc=1.34、曲率係数Uc'=0.46であり、式(1)を満足せず、粒度のよい土でなく、締まりやすい土ではない。   In FIG. 9, the particle size accumulation curve by the particle size test about the comparative example 3 (5% removal) is shown. The result by the method (i) of Example 2 is also shown. In FIG. 10, the data on the passing mass percentage for each particle size in the particle size test of Comparative Example 3 is shown. The soil material (5% removal) of Comparative Example 3 from FIGS. 9 and 10 has the uniformity coefficient Uc = 1.34 and the curvature coefficient Uc ′ = 0.46, does not satisfy the formula (1), is not a soil with good grain size, It's not easy to tighten.

[比較例4,5]
比較例4,5は、実施例1の元の材料を対象にした方法(ii)に対し除去した土を質量割合で20%、50%混合したものである。比較例4,5として、実施例1の元の土材料に除去した土を全体に対する質量割合で20%になるように加えて混合した土材料、および、同様にして50%になるようにして土材料を得た。図11に、比較例4(20%含有)、比較例5(50%含有)についての粒度試験による粒径加積曲線を示す。実施例1の方法(ii)による結果もあわせて示す。図12に、比較例4,5の粒度試験における各粒径について通過質量百分率のデータを示す。図11,図12から比較例4の土材料(20%含有)は、均等係数Uc=6.14、曲率係数Uc'=0.75であり、式(1)を満足せず、粒度のよい土でなく、締まりやすい土ではない。同様に、比較例5の土材料(50%含有)は、均等係数Uc=2.56、曲率係数Uc'=0.95であり、式(1)を満足せず、粒度のよい土でなく、締まりやすい土ではない。
[Comparative Examples 4 and 5]
In Comparative Examples 4 and 5, the soil removed by the method (ii) targeting the original material of Example 1 is mixed by 20% and 50% by mass. As Comparative Examples 4 and 5, the soil material removed by adding the soil removed to the original soil material of Example 1 to a mass ratio of 20% with respect to the whole and mixed so as to be 50% in the same manner. Obtained soil material. In FIG. 11, the particle size accumulation curve by the particle size test about Comparative Example 4 (containing 20%) and Comparative Example 5 (containing 50%) is shown. The result by the method (ii) of Example 1 is also shown. FIG. 12 shows data on the passing mass percentage for each particle size in the particle size test of Comparative Examples 4 and 5. 11 and 12, the soil material (containing 20%) of Comparative Example 4 has an equality coefficient Uc = 6.14 and a curvature coefficient Uc ′ = 0.75, does not satisfy Equation (1), and is not a soil with good particle size. It's not easy to tighten. Similarly, the soil material (containing 50%) of Comparative Example 5 has a uniformity coefficient Uc = 2.56 and a curvature coefficient Uc ′ = 0.95, does not satisfy the formula (1), is not a soil with good grain size, and is easily soiled. is not.

[比較例6,7]
比較例6,7は、実施例2の元の材料を対象にした方法(ii)に対し除去した土を質量割合で20%、50%混合したものである。比較例6,7として、実施例2の元の土材料に除去した土を全体に対する質量割合で20%になるように加えて混合した土材料、および、同様にして50%になるようにして土材料を得た。図13に、比較例6(20%含有)、比較例7(50%含有)についての粒度試験による粒径加積曲線を示す。実施例2の方法(ii)による結果もあわせて示す。図14に、比較例6,7の粒度試験における各粒径について通過質量百分率のデータを示す。図13,図14から比較例6の土材料(20%含有)は、均等係数Uc=2.59、曲率係数Uc'=0.97であり、式(1)を満足せず、粒度のよい土でなく、締まりやすい土ではない。同様に、比較例7の土材料(50%含有)は、均等係数Uc=2.67、曲率係数Uc'=0.84であり、式(1)を満足せず、粒度のよい土でなく、締まりやすい土ではない。
[Comparative Examples 6 and 7]
In Comparative Examples 6 and 7, soil removed by the method (ii) targeting the original material of Example 2 was mixed in a mass ratio of 20% and 50%. As comparative examples 6 and 7, the soil material removed by adding the soil removed to the original soil material of Example 2 to a mass ratio of 20% with respect to the whole and mixed so as to be 50% in the same manner. Obtained soil material. In FIG. 13, the particle size accumulation curve by the particle size test about the comparative example 6 (20% containing) and the comparative example 7 (50% containing) is shown. The result by the method (ii) of Example 2 is also shown. FIG. 14 shows data on the passing mass percentage for each particle size in the particle size test of Comparative Examples 6 and 7. The soil material (containing 20%) of Comparative Example 6 from FIGS. 13 and 14 has the uniformity coefficient Uc = 2.59 and the curvature coefficient Uc ′ = 0.97, does not satisfy the formula (1), and is not a soil with good grain size. It's not easy to tighten. Similarly, the soil material (containing 50%) of Comparative Example 7 has a uniformity coefficient Uc = 2.67 and a curvature coefficient Uc ′ = 0.84, does not satisfy the formula (1), is not a soil with good grain size, and is easily soiled. is not.

以上のように本発明を実施するための形態および実施例について説明したが、本発明はこれらに限定されるものではなく、本発明の技術的思想の範囲内で各種の変形が可能である。たとえば、本発明が適用可能な材料は、砂質土に限るものでなく、礫(レキ)成分でも適用可能であることはもちろんである。   As mentioned above, although the form and Example for implementing this invention were demonstrated, this invention is not limited to these, A various deformation | transformation is possible within the range of the technical idea of this invention. For example, the material to which the present invention can be applied is not limited to sandy soil, and it is needless to say that a gravel component can also be applied.

また、対象とする土材料から除去すべき粒径の範囲を設定するときの粒径とは、粒度試験において用いられるふるいの呼び寸法に対応する粒径であってよいが、これに限定されるものではなく、たとえば、別に設定した呼び寸法のシリーズに対応する粒径であってもよい。   Further, the particle size when setting the range of the particle size to be removed from the target soil material may be a particle size corresponding to the nominal size of the sieve used in the particle size test, but is not limited to this. For example, the particle size may correspond to a series of nominal dimensions set separately.

また、設定した粒径の範囲内の成分を除去するときに用いるふるいの呼び寸法は、上記の粒度試験時に用いるものに限定されず、たとえば、別に設定した呼び寸法のシリーズであってもよい。   Moreover, the nominal size of the sieve used when removing the components within the set particle size range is not limited to that used in the above particle size test, and may be, for example, a series of nominal sizes set separately.

また、土材料が粒度のよい土(締まりやすい土)か否かを判断する基準として、日本統一土質分類法で提示された式(1)を採用したが、本発明は、これに限定されず、別の判断基準であってもよい。   Moreover, although the formula (1) presented in the Japan Unified Soil Classification Method was adopted as a standard for determining whether or not the soil material is a fine-grained soil (soil that is easy to tighten), the present invention is not limited to this. Another criterion may be used.

本発明によれば、破砕工程を経ることなく、また、元々の使用する材料に対し新たな材料を用意することなく、締め固めが容易な土材料を作製できるので、コストがかさまずに、たとえば、盛土をよく締め固めて築造でき、また、掘削した土を原位置に埋め戻す際にその土をよく締め固めることができる。   According to the present invention, it is possible to produce a soil material that is easy to compact without going through a crushing step and without preparing a new material for the material to be originally used. The embankment can be well compacted and built, and when the excavated soil is backfilled in place, the soil can be compacted well.

10 機械式振動ふるい装置
11 第1のふるい部
11a 振動部
12 第2のふるい部
12a 振動部
DESCRIPTION OF SYMBOLS 10 Mechanical vibration sieve apparatus 11 1st sieve part 11a Vibration part 12 2nd sieve part 12a Vibration part

Claims (6)

対象とする土材料の粒度試験を実施し粒径加積曲線を作成し、
前記対象とする土材料が前記粒径加積曲線に基づいて締まりやすい土材料であるか否かを判断し、
前記対象とする土材料が締まりやすい土材料でないと判断された場合、前記粒径加積曲線から求めた通過質量百分率50%のときの中央粒径D50よりも小さい粒径の範囲において全体に対する質量割合で10〜30%を占めかつ前記中央粒径D50に近い粒径の範囲を前記粒径加積曲線に基づいて設定し、
前記対象とする土材料から前記設定した粒径の範囲内の成分を除去することで締め固め容易な土材料を作製することを特徴とする締め固め容易な土材料の作製方法。ただし、前記対象とする土材料から単一粒径の土材料は除かれる。
Conduct a particle size test of the target soil material, create a particle size accumulation curve,
Determine whether the target soil material is a soil material that is easy to tighten based on the particle size accumulation curve,
When it is determined that the target soil material is not a soil material that is easy to tighten , the mass relative to the whole in the range of the particle size smaller than the median particle size D50 when the passing mass percentage is 50% obtained from the particle size accumulation curve A range of the particle size that occupies 10-30% in proportion and close to the median particle size D50 is set based on the particle size accumulation curve,
A method for producing an easily compacted soil material, comprising preparing an easily compacted soil material by removing components within the set particle diameter range from the target soil material. However, the soil material having a single particle diameter is excluded from the target soil material.
前記対象とする土材料を、前記設定された粒径の範囲の上限よりも一段階大きいふるいを上段に備えるとともに前記設定された粒径の範囲の下限よりも一段階小さいふるいを下段に備えるふるい装置にかけ、前記上段のふるいを通過し前記下段のふるいに留まる土粒子を除去することで、前記設定した粒径の範囲内の成分を除去する請求項1に記載の締め固め容易な土材料の作製方法。   The target soil material is provided with a sieve that is one step larger than the upper limit of the set particle size range in the upper stage and a sieve that is one step smaller than the lower limit of the set particle size range in the lower stage. The earthen material for easy compaction according to claim 1, wherein the components within the range of the set particle diameter are removed by removing the soil particles passing through the upper screen and remaining on the lower screen through an apparatus. Manufacturing method. 前記除去された成分の土材料を、前記対象とする元の土材料に全体に対する質量割合で30〜40%の範囲になるように調整して加えて混合することを特徴とする請求項1または2に記載の締め固め容易な土材料の作製方法。   The soil material of the removed component is added to and mixed with the original soil material as a target so as to be in a range of 30 to 40% by mass ratio with respect to the whole. 2. A method for producing an easily compacted earth material according to 2. 前記対象の土材料が以下の式(1)を満たさない場合、締まりやすい土材料でないと判断することを特徴とする請求項1乃至3のいずれか1項に記載の締め固め容易な土材料の作製方法。
1<Uc'≦√Uc (1)
ただし、Uc:均等係数(=D60/D10)
D60:前記粒径加積曲線において通過質量百分率60%のときの粒径
D10:前記粒径加積曲線において通過質量百分率10%のときの粒径
Uc':曲率係数(=(D30)2/(D60×D10))
D30:前記粒径加積曲線において通過質量百分率30%のときの粒径
If the soil material of the object does not satisfy the equation (1) follows, easy tighten compacted according to any one of Motomeko 1 to 3, characterized in that it is determined that not tight easy soil material A method for producing soil materials.
1 <Uc '≦ √Uc (1)
However, Uc: Equal coefficient (= D60 / D10)
D60: particle diameter when the passing mass percentage of 60% in the cumulative volume size curve
D10: particle diameter when the passing mass percentage of 10% in the cumulative volume size curve
Uc ': Curvature coefficient (= (D30) 2 / (D60 × D10))
D30: particle diameter when the passing mass percentage of 30% in the cumulative volume size curve
盛土を築造する方法であって、
土材料を請求項1乃至4のいずれか1項に記載の作製方法によって締め固め容易な土材料に改良し、
前記改良した土材料により盛土の築造を行うことを特徴とする盛土築造方法。
A method of building embankments,
The soil material is improved to a soil material that is easy to compact by the production method according to any one of claims 1 to 4,
An embankment construction method comprising constructing an embankment with the improved soil material.
掘削した土を原位置に埋め戻す方法であって、
前記掘削した土を請求項1乃至4のいずれか1項に記載の作製方法によって締め固め容易な土材料に改良し、
前記改良した土材料を埋め戻すことを特徴とする土埋戻し方法。
A method of backfilling excavated soil in its original position,
The excavated soil is improved into an easily compacted soil material by the production method according to any one of claims 1 to 4,
A soil backfilling method comprising backfilling the improved soil material.
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