DE1215063B - Mixture for fastening to the ground - Google Patents

Description

Mixture for ground reinforcement The invention relates to a mixture for ground reinforcement, especially for road construction, a pozzolan, a plastic Contains soil and lime.

The term "road construction" as used herein closes load-bearing foundations of numerous types, such as B. Parking lots, runways, highways, Motorways and the like. Numerous floors, including highly plastic floors, can be implemented successfully with quick lime and a pozzolan such as fly ash, whereby the product obtained hardens and at the same time a very useful, hard, stone-like one Material results. Although such compositions set relatively slowly, they show good compressive strength even during the first stages of the curing period. Such compositions develop excellently after a sufficient curing time Compressive strength. They have enough stability as a resilient foundation for Road construction and other measures.

It has been found, however, that certain of the more plastic soils after implementation with quicklime and a pozzolan under adverse weather conditions durability is lacking during the early stages of the curing period. Desirable is the manufacture of a road surface immediately after its manufacture has good compressive strength. She must retain this property even if it is exposed to adverse weather conditions such as dampening and drying alternating, frost break or alternating freezing and thawing. The ability of one Road surface or other resilient foundations, unfavorable weather conditions to withstand curing during the first stages, while such Base or such a foundation is also exposed to heavy machine loads is hereinafter referred to as the durability of the floor.

Attempts to improve the initial durability properties of plastic Improving soils by adding quick lime and fly ash has not been successful. If you combine an A-6 or A-7 clayey soil with, for example, fly ash, so, with the progressive addition of quick lime, the retention capacity actually decreases for water of the composition. This shows that the quick lime is not uniform with the other ingredients acts to increase the initial durability of the mixture to improve.

Soil classes A-6 and A-7 belong to a group of naturally occurring ones Soils with a degree of fineness below 1.7. “Degree of fineness” is a standard particle size designation understood, which has been determined by sieve analysis.

The following standard sieves are used: Millimeter sieve opening (sieve No. ASTM) 4.76 .................... 4 2.38 ................... 8 1.19 .................... 16 0.59 .................... 30 0.297 ................... 50 0.149 ... ................ 100 The fineness of a material is calculated by adding that of each of the individual sieves retained percentage of the material and division of the Sum by 100.

Such floors correspond in the classification of the USA. Public Roads Administration classification. The A-6 floors are essentially plastic Clay soils, of which generally 75% or more through a sieve of 0.07 mm sieve opening go through.

The A-7 floors are also clayey materials with undesirable elasticity and spatial shrinkage properties. The A-6 and A-7 trays are generally regarded as poor, inferior materials for road and highway construction.

The mixture according to the invention for paving the ground contains an im essential water-insoluble and chemically inert to pozzolan and lime, inorganic aggregate, its Particle diameter mainly is in a size range of about 0.42 to about 12.7 mm, and the mixing ratio their proportions, based on the total weight of pozzolan, are plastic soil and aggregate as 100%, 5 to 25% pozzolan, 35 to 75% plastic soil and 20 to 50% aggregate and also in percent by weight of the above total weight 2 to 9% lime.

It has now been found that soils are very plastic when you use them certain amounts of quicklime, a chemically inert aggregate and a pozzolan treated, remarkably improved durability during the first few sections show the curing period.

The proportions of the components to one another are essential, such as shown below. It has been found that the retention capacity for water of the compositions according to the invention with the addition of quick lime decreases when the Compositions a small amount of an aggregate is incorporated into that but on the other hand, surprisingly, the retention capacity for water with the addition of quick lime increases when the aggregate content is 20 to 50 percent by weight, based on on the total weight of pozzolan plus soil plus aggregate.

The term "quick lime" as used here is intended to mean burnt Lime, hydrated lime and slaked lime are to be understood.

The term "pozzolan", as it is used here, is intended to represent a silicon or denote aluminum-containing, mineral material that is either artificial or can be natural and which itself has little or no value as a binder; However, this in finely divided form and in the presence of moisture is chemically can react with calcium hydroxide at ordinary temperatures and thereby compounds forms, which have binding properties.

A particular example of a finely divided pozzolan is that in Artificial material known in the art as fly ash. The expression "fly ash" is used here for finely divided ash residues caused by the incineration of pulverized coal are produced, the ashes of which with those coming from the incinerator Gases is blown off. The fly ash is so finely divided that at least approximately Pass 70% through a sieve with a mesh size of 0.074 mm. The ones from the Fly ash collected from exhaust gases is referred to below as raw fly ash.

Other forms of pozzolan are naturally occurring pozzolans and volcanic ash like those found near Puzzuoli in Italy. Next belong in addition raw or calcined tuff stones, diatomaceous earth, pumice stones, opal, slate and trasse (trasses). Artificially produced species are, for example, fly ash, Boiler slag and fly ash. Other pozzolans are kieselguhr, diatomaceous earth, and Slate pozzolans; `the about 50 to 70 percent by weight Si02, about 5 to 10 percent by weight Fe 2 O 3, approximately 10 to 30 percent by weight A1 2 O 3 and small amounts Contain CaO and MgO.

The term "plastic floors" as used here denotes natural, essentially inorganic materials such as clay, loam or sludge, the constituents of which are so fine that the normal soil appraisal method cannot this degree of fineness is recorded. Most of the soil goes through a standard sieve 0.149 mm clear mesh size. Although this material is called "inorganic" is supposed to ensure the presence of smaller proportions of organic materials cannot be ruled out if only the fine material is predominantly inorganic. The term "plastic soil", as defined above, includes all soils that have a plasticity index greater than 15, all floors with a plasticity index from about 9 to 15 if more than about 15 weight percent of these soils through a standard sieve with a mesh size of 0.074 mm and all bottoms, which have a plasticity index less than about 9, if more than about 35 percent by weight of the soil through a standard sieve with a mesh size of 0.074 mm go through.

The plasticity index of a soil is the numerical difference between the liquid limit and the plastic limit of the soil. The liquid limit of the soil is the water content at which the soil differs from plastic or semi-solid State changes to the liquid state. The plastic limit of the soil is the lowest water content at which the soil becomes plastic, or the water content, in which the soil changes from solid to semi-solid. Test for the fluid limit and the plastic limit are known in the art.

Under ASTM Numbers D 423-54.T and D 424-54T (American Society for Testing Materials, Philadelphia, Pennsylvania, 1954) become standard procedures to determine the liquid limit and the plastic limit of a soil and thus its plasticity index is reproduced.

As used herein, the term "aggregate" refers to natural or man-made inorganic materials that are essentially chemically inert to fly ash and quicklime and are essentially insoluble in water. These include limestone sieves, natural sand, sand made from stone, blast furnace slag, gravel or other substances with similar properties. A relatively coarse aggregate is included as well as fine aggregate. As used herein, an aggregate is a mixture of finely divided particles which can include limited amounts of relatively coarse particles, even particles up to about 1.27 cm in size. Approximately the majority of the aggregate preferably consists of particles about 0.42 to 12.7 mm in size. Preferably the size of the aggregate falls within the following range: Sieve through portion (Millimeter clear mesh size) in percent by weight 12.7 90 to 100 4.76 (No. 4) 75 to 100 2.00 (No. 10) 40 to 90 0.42 (No. 40) 5 to 35 0.074 (# 200) 0 to 15 The relative proportions of the major ingredients of the compositions of the invention are essential. If the proportions are kept within the specified range, an astonishing improvement in durability is achieved in the early stages of the curing period. The following mixtures are preferably used: Weight percent Material (calculated from the total amount of pozzolan, soil and aggregate) Pozzolan ............ 5 to 25 Soil .............. 35 to 75 Unit ............ 20 to 50 Quick lime ............. 2 to 9 As already indicated, the sum of the percentages of pozzolan plus soil plus aggregate is essentially approximately 100. This is the calculation basis which is used when specifying the proportions of the constituents of the compositions according to the invention.

The durability properties of the compositions of the invention are determined by examining the disintegration of samples under water.

The disintegration tests under water show that at about 20 percent by weight of the aggregate the aggregate with the quick lime, the pozzolan and the soil so reacts in the same direction that the four components look more like a mixture behave as like separate, distinct materials. With less as about 20 weight percent aggregate causes the progressive addition from quick lime to the ground plus pozzolan plus aggregate a decrease in retention capacity for water of composition. However, if you increase the proportion of the aggregate over 20 percent by weight, the progressive addition of quicklime to the soil increases plus pozzolan plus additional tone the retention capacity for water. This result is completely surprising. Perhaps it explains why the composition of the invention behave so favorably. Repeated attempts have the fact of this Phenomenon is corroborated as well as its practical value.

The compositions of the invention can be in any conventional Way, for example by simply mixing the solid ingredients, preferably in the presence of water. Approximately add water to the mixture the amount required to achieve the known optimum moisture content is.

The optimal moisture content is modified by the well known Proctorprobe determined. The optimal moisture content of a soil mix is the moisture content at which the soil-water mixture has its maximum density (dry) - or the maximum dry weight of the solids per unit volume. In practice, the optimal moisture content will vary with any given soil and any particular soil mix, generally between 8 and 25 percent by weight Moisture calculated on the total dry weight of the solids. While admitting of water to the mixtures according to the invention, the water content should preferably be can be adjusted to a range of 70 to 130: 1 / o of the optimum water content. Thus, the water content of the resulting composition can be from about 5 to 32 percent by weight vary based on the total weight of quicklime, pozzolan, soil and aggregate for different floors.

After mixing you can choose the soil composition you want Shaping. Developed after a very short hardening time, e.g. 2 to 5 days the material has considerable strength even when it is wet. However developed the cement-like bond of the mixture is so slow that even after one Week the shaped mixture can be easily deformed and reshaped. To Hardening for a considerable time, for example a month, has the Mixture has a very considerable compressive strength. After a year it is received Product exceptionally firm.

The following examples illustrate the invention. Example 1 Soil derived from a plastic A-6 clay from southeastern Pennsylvania has the following sieve analysis: Sieve through portion (Millimeter clear mesh size) in percent by weight 19.05 100.0 9.53 99.0 4.76 (# 4) 98.0 2.00 (# 10 97.6 0.42 (# 40) 97.2 0.250 (# 60) 97.0 0.074 (# 200) 96.5 The soil has a plasticity index of 14 and a liquid limit of 32. The soil was mixed with hydrate lime, fly ash and dolomite limestone sieves along with the optimal amount of water. The proportions of the solids were as follows: Weight percent (calculated net on total weight Soil, fly ash and Limestone sieves) A-6 bottom ................ 70 Hydrate lime ............. ... 9 Fly ash ................. 10 Limestone sieving ...... 20 The obtained mixture was allowed to cure after compression under natural conditions for 3 days. The samples of the product obtained (compressed cubes) were immersed in water for 3 hours. They practically showed no weight loss. In addition, the mixture had sufficient durability to support heavy vehicles that would be driven over the mixture even when it was subjected to alternate wetting and re-drying. This is in contrast to the very low strength of the natural A-6 soil. Test cubes made from natural A-6 soil disintegrated practically completely within a few minutes when subjected to atmospheric conditions for 3 days and then tested for disintegration under water. After curing for 21 days under natural environmental conditions, the product obtained showed excellent compressive strength of approximately 21 kg / cm2 in contrast to the compressive strength of natural soil, which is practically zero. The product obtained showed greatly improved resistance to freezing and thawing and to wetting and drying as indicated by a standard wire brush test; this proved that such a product withstood numerous work cycles, in contrast to natural soil, which could not withstand a single work cycle. Example 2 The following compositions have high strength early (3 days) and show excellent processing properties after 21 days of cure. Example 3 A mixture of 90 percent by weight of A-7 plastic soil, 10 percent by weight of fly ash, and 5 percent by weight of quicklime was prepared. After mixing with the optimal amount of water and curing for three days under natural ambient conditions, the mixture was tested for durability by submerging standard test cubes in water. The test cubes disintegrated so quickly that no quantitative measurement of the loss was possible.

A composition of 60 percent by weight of the same A-7 soil, 10 percent by weight fly ash, 5 percent by weight quicklime, 30 percent by weight limestone sieves was produced. After mixing with the optimal amount of water and hardening for three days test cubes of the mixture obtained were made under natural environmental conditions submerged under water and tested for decay. After immersion for 3 hours practically no weight loss was observed on the cube.

Example 4 In a series of experiments, a plastic kaolin (A-7) was stabilized with varying amounts of quicklime, fly ash and limestone sieves. The samples were allowed to harden for a short time, then water was added and each sample was tested for water retention. Each soil sample was placed on top of a piece of filter paper carried by the flat, perforated ceramic base of a Buchner nut. Standard suction was then carried out. After a while, the filter paper or the ceramic pad got wet. The time increments were measured and noted as the value of the retention capacity for water. The following results were obtained: Table II Effect of quick lime on the value of retention capacity for water from stabilized kaolin (Weights in kilograms) Weight weight weight of weight value of of the surcharge of the retention Kaolins fly ash fabric calcium carbonate assets (sifted) for water 241.13 26.79 0 0 88.41 241.13 26.79 0 8; 04 83; 06 241.13 26.79 0 16.08 77.69 241.13 26.79 0 24.31 I 72.43 Table II (continued) Weight weight weight of weight withered des of the surcharge of the retention Kaolins fly ash substance quick lime asset (sifted) for water 187.55 26.79 53.58 0 66.98 187.55 26.79. 53.58 8.04 64.30 187.55 26.79 53.58 16.08 50.90 187.55 26.79 53.58 24.31 53.58 133.96 26.79 107.17 0 53.58 133.96 26.79 107.17 8.04 53.58 133.96 26.79 107.17 16.08 56.26 133.96 26.79 107.17 24.31 61.62 80.37 26.79 160.75 0 40.18 80.37 26.79 160.75 8.04 45.54 80.37 26.79 160.75 16.08 53.58 80.37 26.79 160.75 24.31 50.90 The above example shows the following: While the value of the retention capacity for water of the composition decreases with the addition of quicklime, if only a small amount of aggregate is present, this effect is reversed, and the value of the retention capacity for water of the composition increases with the addition of quicklime, if the Surcharge is between 20 and 50 percent by weight. This effect shows that a conversion occurs between quick lime, fly ash, soil and aggregate. Example s A series of disintegration tests were carried out using Maryland A-7 clay. Various samples were prepared containing varying amounts of limestone screen aggregate. All samples were immersed in water for 60 hours, after which they were examined for hardness, compressive strength and underwater disintegration. The results are given in the following table: This table shows that underwater disintegration is greatly reduced and virtually eliminated when the percentage of aggregate approaches about 20 percent by weight while the amounts of quicklime and fly ash are kept constant. This shows that conversion occurs at about 20 percent by weight of the aggregate.

Example 6 Mixtures were made of approximately 10 percent by weight of a finely powdered volcanic pozzolan obtained from a natural one Deposited in the Canary Islands and made up of approximately 60% by weight of one plastic soil and about 30 percent by weight of an aggregate to which approximately 5 percent by weight quicklime were added, the percentage being Quick lime was calculated on the total weight of pozzolan, soil and aggregate. After mixing with the optimal amount of water and hardening under natural for three days Ambient conditions, the mixtures were tested for durability by standard test cubes were dipped under water. There was essentially no weight loss after immersing the dice for three hours found what an excellent one Proves durability.

If a plastic soil with a high retention capacity for water mixed with an aggregate to make the soil for use in road construction to improve, the results are unsatisfactory even if one adds a very large amount of aggregate. For example, if over 50% aggregate added to a plastic mud or a plastic clay, has the product very quickly shows defects when it is subjected to the changing influence of moistening and is subjected to drying or freezing and thawing and the simultaneous action from heavy loads. It is accordingly surprising that the same soil solidifies and a product with excellent durability among the same Conditions formed when small amounts of quicklime and fly ash and for example only 20 percent by weight of aggregate can be added to the floor. While the direct Adding aggregate to plastic soil is very costly because of the large size required amount, the same soils are effective and economical according to the invention solidified using much smaller amounts of aggregate along with small amounts of fly ash and quick lime with a considerable reduction in the overall expenditure.

It should be noted that coarse aggregates such as 1.27 cm stones or even larger stones can be incorporated into the soil mixture.

Claims (2)

Claims: 1. Mixture for ground reinforcement, in particular for road construction, which contains a pozzolan, a plastic soil and lime, d a by characterized as being substantially water-insoluble and inorganic aggregate which is chemically inert against the pozzolan and the lime contains, the particle diameter of which mainly in a size range of about 0.42 to about 12.7 mm, and that the mixing ratio of the proportions, based on the total weight of pozzolan, plastic soil and aggregate as 100%, 5 to 25% pozzolan, 35 to 7511 / o plastic soil and 20 to 5011 / o aggregate and in percent by weight of the above total weight is 2 to 911 / o lime. 2. Mixture for ground reinforcement according to claim 1, characterized in that the plastic soil contains a soil with a plasticity index below about 9 if more than about 35 percent by weight of the soil pass through a standard sieve with 0.074 mm clear mesh size, or a soil with a plasticity index from about 9 to 15 when greater than about 15 percent by weight of the soil passes through a standard 0.074 mm mesh screen, or a soil having a plasticity index greater than about 15. References under consideration: USA. Patent Nos. 2,564,690, 2,250,107; French patent specification No. 1117 781.