JP5075788B2 - Method for improving construction generated soil mainly composed of type 4 construction generated soil and construction plant improving soil composed mainly of type 4 construction generated soil. - Google Patents

Description

The present invention improves the type 4 construction generated soil (cohesive soil and equivalents) generated at construction sites such as roads and uses it for road construction, etc., backfill road floor materials, pipe protective materials (recycled sand) Further, the present invention relates to a method of regenerating as roadbed material and the like, and an improved plant that implements the method.
According to the present invention, the fourth type construction generated soil generated at construction sites such as road construction and water and sewage construction is a natural material quarry (mountain soil), crushed stone, gravel, sand, road protection and pipe protection material. And it became possible to recycle as roadbed material.

Among construction generated soil generated at construction sites such as road construction and water and sewage, viscous soil and equivalents (classified as “Class 4 construction generated soil” by the Ministry of Land, Infrastructure, Transport and Tourism) It is a relatively soft soil having a cone index, which is a value representing the resistance per unit area, of 200 KN / m ² or more and less than 400 KN / m ² . Generally called fine-grained soil, it is an aggregate of small soil particles, and is formed with a skeleton in which silt particles are connected by clay particles and clay particles are connected by colloids. Unlike the single-grain structure of coarse-grained soil, the fine-grained skeleton has a large number of small soil particles that form a group, and this group is the unit of the skeleton.
This is called a honeycomb structure, and the force to create a skeleton is called adhesive force or cohesive force. What is sandwiched between the contact portions of the soil particles is compressed to bond a strong skeleton, but once twisted, it becomes very soft. This is because the soil particles themselves are fine aggregates, so that the skeleton is weak, and the soil is sensitive soil in which the structural bonds are broken. Since fine-grained soil is an aggregate of fine soil particles, the amount of gaps is small. Since the amount of the gap is a water permeability factor, it is a soil quality that can be effectively used only in a portion that requires water shielding or a portion that is less affected by drying shrinkage (water surface landfill).
Depending on the region and site conditions, construction soil from type 1 to type 4 may be generated at one construction site, especially in construction that is relatively deeply excavated, such as sewerage construction. There are many types of 4 types of construction soil.
Type 1 to Type 3 construction generated soil can be used for backfilling, backfilling, embankment, etc. if sorted, but the fourth type construction generated soil is due to securing temporary storage facilities (stock yards) and cost. It is currently being landfilled (disposed) in a mixed state.
In addition, there are “fluidization treatment”, “firing” and the like as methods for treating the fourth type construction generated soil. In the fluidization treatment, the fourth type construction generated soil is dissolved in water, and a large amount of additive is added to form a slurry, which is used as a pipe protective material.
In the firing, the moisture of the fourth type construction generated soil is forcibly evaporated by thermal power, is made ash-like or granular, and is mixed with the soil to be used as a backfill material. In the case of fluidization, water treatment is required, and a large amount of additive is also required.
Moreover, in the case of baking, a thermal power is required and a dioxin problem is also anxious. Moreover, it is necessary to suppress mixing of the 1st type-3rd type construction generation soil for fluidization and baking as much as possible.
In the present invention, it was aimed at unified recycling of all construction generated soil (first to fourth construction generated soil) that does not require water treatment, thermal power, and a large amount of additive.

Japanese Patent Laid-Open No. 10-224853, JP 2000-50474, JP 2000-358101 A, JP 2001-251440 A

The type 4 construction soil generated by road construction and water and sewage works is disposed of as waste in designated landfills such as landfills. However, the number of landfills is decreasing year by year, and is far away. 4th class construction has occurred because it has been dumped and the return path of the dump truck has become empty, or it has been disposed of in a state where it was originally mixed with the first to third class construction soil that can be used. Soil disposal has become inefficient and uneconomical.
Further, in conventional road construction, various problems such as collection of earth and sand for backfilling such as roadbed materials and roadbed materials, disposal of construction generated soil, and transportation cost of construction generated soil have occurred.
The collection of earth and sand for roadbed materials and roadbed materials destroys the natural environment and depletes valuable natural resources, so the impact on the environment is serious, and the distance to the collection site is far away. It is inefficient because the outbound route becomes empty.
The landfill disposal site is no longer needed by improving and modifying various types of construction soil, including troublesome type 4 construction soil, which is troublesome for the above reasons, and recycling it to various products. In addition, there is a need for a recycling-type construction soil recycling system that does not require the collection of new materials.
The purpose of the present invention is to recycle all construction-generated soil including the fourth-generation construction generated soil as various products such as roadbed materials, so that the reuse rate is 100%. The problem is to solve the problems of waste disposal sites and environmental problems.

In the present invention, 1% lime in mass ratio is added to and mixed with the fourth type construction generated soil (cohesive soil and the like), and this mixture is mixed with those having a particle size of 100 mm or more and in the range of 100 mm-40 mm. Screening is carried out between those having a particle size of 40 mm or less and holding a mixture having a screened particle size of 40 mm or less. The particle size is 120 mm from the first to third type construction generated soil (hereinafter referred to as high quality construction generated soil). The high quality construction generated soil from which the above is removed is screened into those with a particle size of 20 mm or more and those with a particle size of 20 mm or less. Sieving and those below 30mm,
Hold the crushed soil of high quality construction generated soil having a screened particle size of 20 mm or less and good quality construction generated soil having a particle size of 30 mm or less, and the fourth type construction generated soil and lime having a screened particle size of 40 mm or less And a mixture of high-quality construction generated soil of 20 mm or less screened by a sieve and crushed soil of high-quality construction generated soil of 30 mm or less screened at a mass ratio of 5: 3: 2.
A mixture of Type 4 construction generated soil with a screened particle size of 40 mm or less and lime, a mixture of high quality construction generated soil of 20 mm or less screened by sieving, and a crushed soil of high quality construction generated soil of 30 mm or less screened. Improvement of construction soil mainly composed of type 4 construction soil characterized by mixing 1.6% cement and about 0.4% lime as stabilizer. The method and the improved plant that implemented it.
According to the present invention, the type 4 construction soil that becomes waste is improved to a quality equal to or higher than that of conventional road backfill materials and roadbed materials, and can be reused, enabling effective use of resources and prevention of environmental destruction. Become.

Any construction generated soil (first to fourth types) generated by road construction and water and sewage construction, etc., by the construction improved soil mainly composed of the fourth type construction generated soil of the present invention and the plant where the construction is performed. Construction soil) will be improved and improved, and construction waste soil of all properties can be recycled into products.
This eliminates the need for a landfill site to dispose of the type 4 construction generated soil, as well as the effective use of waste as a resource, eliminating the need to collect new materials and creating an environment-friendly recycling-type construction generated soil. A reproduction system can be realized.
In addition, by utilizing the improved plant of the present invention, the construction waste recycling site and the product shipping ground become the same. It is possible to solve various problems that occur with construction work at the same time.
In addition, recently, reused products obtained by crushing concrete lumps and asphalt lumps, or construction soil and crushed concrete lumps and asphalt lumps are mixed and used for roadbed materials and roadbed materials. More and more local governments say that when excavated, they should be treated as industrial waste instead of construction soil.
Furthermore, there are concerns about elution of hexavalent chromium when recycling (reworking) concrete blocks, and elution of volatile organic substances when recycling (reworking) asphalt blocks.
In the present invention, since no concrete lumps and asphalt lumps are used and can be regenerated only with construction generated soil, they can be improved any number of times because they are construction generated soil even if they are dug up again. A recycling-type construction-generated soil recycling system can be realized.

FIG. 1 is a diagram showing a configuration of an improvement plant for construction generated soil mainly composed of type 4 construction generated soil in which the method for improving construction generated soil mainly composed of type 4 construction generated soil according to the present invention is implemented.
In FIG. 1, 10 is a raw material yard for the fourth type construction generated soil.
11 is a loading machine for the fourth type construction generated soil, and 12 is a hopper into which the fourth type construction generated soil is charged. Reference numeral 13 denotes a belt-type fixed supply machine that sends out the fourth type construction generated soil of the hopper 12.
Reference numeral 14 denotes a first belt type conveyor. Reference numeral 15 denotes a lime silo that stores lime as a reforming material, and 16.17 denotes a screw-type metering feeder that delivers the lime of the lime silo 15.
Reference numeral 18 denotes a cement silo for storing cement as a modifying material, and 19 denotes a screw-type quantitative feeder for sending cement of the cement silo 18.
In the first belt type conveyor 14, lime having a mass ratio of about 1% is added to the fourth type construction generated soil.

Reference numeral 20 denotes a rotary sieve that screens a mixture of the fourth type construction generated soil and lime into a mixture having a particle size of 100 mm or more, a range of 100 mm-40 mm, and a size of 40 mm or less.
21 is a stockyard of a mixture of soil and lime of the 4th type construction with a particle size of 100 mm or more, which is screened by the rotary sieve 20, and 22 is a fourth type of construction with a particle size of 40-100mm which is screened by the rotary screen 20. A stock yard of a mixture of soil and lime.
24 is a viscous soil hopper that holds the mixture of the fourth type construction generated soil and lime having a particle size of 40 mm or less, which is screened by the rotary sieve 20, and 25 is the fourth type construction generated soil of the viscous soil hopper 24 and the mixture of lime. It is a belt-type fixed quantity feeder that sends out.
Reference numeral 30 denotes a raw material yard for first to third type construction generated soil (hereinafter referred to as high quality construction generated soil). 31 is a loading machine for high quality construction generated soil. 32 is a high-quality construction-generated soil hopper with a fixed sieve that removes particles with a particle size of 120 mm or more from high-quality construction-generated soil, 33 is a high-quality construction with a particle size of 120 mm or more removed by the fixed screen of the high-quality construction generated soil hopper It is a stock yard of the soil where it occurs

Reference numeral 34 denotes a belt-type quantitative supply machine for delivering high-quality construction-generated soil hopper 32. Reference numeral 35 denotes a second belt type conveyor.
Reference numeral 36 denotes a first vibration sieve that screens high-quality construction generated soil from which particles having a particle size of 120 mm or more have been removed into those having a particle size of 20 mm or more and 20 mm or less. Reference numeral 37.38.41 denotes third, fourth and fifth belt type conveyors.
Reference numeral 39 denotes an impact type crusher that crushes high-quality construction generated soil having a particle size of 20 mm or more, which is screened by the first vibrating screen 36. Reference numeral 40 denotes a second vibration sieve that screens the crushed soil of high-quality construction generated soil crushed by the impact crusher 39 into those having a particle size of 30 mm or more and 30 mm or less. The crushed soil of high-quality construction generated soil having a particle size of 30 mm or more screened by the second vibrating screen 40 is crushed again in addition to the impact crusher.
Reference numeral 42 denotes a second hopper that holds high-quality construction-generated soil having a particle size of 30 mm or less that has been screened by the second vibrating screen.

Reference numeral 43 denotes a first hopper that holds high-quality construction-generated soil having a particle size of 20 mm or less that has been screened by the first vibrating screen.
44 is a belt-type transporter for transporting the high-quality construction generated soil of the hopper 43, the crushed soil of the hopper 42, the mixture of the fourth type construction generated soil of the clay hopper 24 and the lime, the lime of the lime silo 15 and the cement of the cement silo 18. It is.
Reference numeral 50 denotes a high-quality construction-generated soil having a particle size of 20 mm or less, which is screened by the mixture of the fourth type construction-generated soil and lime held in the viscous soil hopper 24 and the first vibrating screen held in the first hopper 43. And mixed with crushed soil of high-quality construction generated soil having a particle size of 30 mm or less, which is screened by the second vibrating screen held by the second hopper 42, with lime and cement added, and improved roadbed material Is a mixer that produces
Reference numeral 51 denotes a belt-type transporter that transports the improved roadbed material manufactured by the mixer 50, and 52 denotes a stockyard for the improved roadbed material.

Reference numeral 60 denotes a plant part that manufactures an improved pipe protective material (improved recycled sand) using the improved roadbed material as a raw material.
61 is an improved roadbed material feeder. Reference numeral 62 denotes a hopper into which the improved roadbed material is charged, and 63 denotes a belt type quantitative feeder for delivering the improved roadbed material of the hopper 62. Reference numeral 64 is a belt-type transporter for transporting the improved roadbed material, and 65 is a 7 mm vibrating screen for producing the improved pipe protection material by sieving the improved roadbed material.
66 is a stock yard of improved pipe protective material (modified reclaimed sand) having a particle size of 7 mm or less, which is screened by vibrating screen 65, 67 is an improved roadbed material (modified roadbed) having a particle size of 7 mm or more screened by vibrating screen 65 Stock yard).
The improved roadbed material having a particle size of the stock yard 66 of 7 mm or less is used as an improved pipe protection material (improved recycled sand).
70 is a plant part which manufactures an improved roadbed material from the improved roadbed material.
71 is an improved roadbed material feeder for the stock yards 66 and 67. Reference numeral 72 denotes a hopper into which an improved roadbed material having a particle size of 7 mm or less is charged. Reference numeral 73 denotes a belt-type quantitative feeder that delivers the improved roadbed material of the hopper 72.
74 is a hopper into which an improved roadbed material having a particle size of 7 mm or more is charged, and 75 is a belt-type quantitative feeder for delivering the improved roadbed material of the hopper 74. 76 is a belt type conveying machine that conveys the improved roadbed material sent from the belt type quantitative feeders 73 and 75, and 77 is a mixer. 78 is a stockyard for improved roadbed material.

The operation of the improved plant for construction generated soil mainly composed of the fourth type construction generated soil as described above will be described as follows.
The fourth type construction generated soil in the raw material yard 10 of the fourth type construction generated soil is put into the cohesive soil hopper 12 by the charging machine 11, and the fourth type construction generated soil is sent out by the belt type quantitative supply machine 13, It is added to one belt type conveyor 14.
From the lime silo 15, about 1% of lime in the mass ratio of the fourth type construction generated soil is sent out by the screw type quantitative feeder 16 and added to the first belt type conveyor 14.
The mixture of the fourth type construction generated soil and lime in which about 1% of lime in mass ratio is added from the lime silo 15 to the fourth type construction generated soil of the first belt-type transporting machine 14 is divided by the rotary sieve 20 into the particles. Screens are classified into those having a diameter of 100 mm or more, those having a diameter in the range of 100 mm-40 mm, and those having a diameter of 40 mm or less.
The rotary sieve 20 uses a sieve in which a special rod with a square cross section is formed in a cylindrical shape instead of a net, and performs screening while rotating the cylinder. It has the feature that there is almost no residence even in the soil where construction occurs.

The mixture of the fourth type construction generated soil and lime having a particle size of 100 mm or more screened by the rotary sieve 20 is stored in the stock yard 21, and the 40-100 mm fourth type construction generated soil and lime screened by the rotary sieve 20 is stored. This mixture is stored in the stockyard 22.
Since the fourth type construction generated soil stored in the stock yard 21.22 is preliminarily added with lime, the crushed effect can be expected by putting it in the rotary sieve again.
In particular, the construction generated soil stored in the stock yard 21 is mainly gravels (stones) mixed with the type 4 construction generated soil. The clay soil mass is put into the hopper 12 after crushing into the construction generated soil hopper 32.
The mixture of the fourth-class construction generated soil and lime having a particle size of 40 mm or less, which is screened by the rotary sieve 20, is held in the viscous soil hopper 24.
The first to third type construction generated soil (hereinafter referred to as high quality construction generated soil) in the raw material yard 30 is transferred to a high quality construction generated soil hopper 32 having a fixed sieve that removes particles having a particle size of 120 mm or more by the charging machine 31. The high quality construction generated soil having a particle size of 120 mm or more is removed and stored in the stock yard 33 by the fixed sieve, and the high quality construction generated soil having a particle size of 120 mm or less is stored in the high quality construction generated soil hopper 32.
The reason for sieving with a 120 mm sieve is that the maximum particle size that can be charged into the crusher, which is the next process, is about 120 mm. The hopper 32 is charged.
High quality construction generated soil of the high quality construction generated soil hopper 32 is sent out by a belt-type fixed supply device 34 and added to the first vibrating screen 36, and is screened into those having a particle size of 20 mm or more and 20 mm or less.

The high-quality construction generated soil having a particle size of 20 mm or more screened by the first vibrating screen 36 is added to the impact-type crusher 39 by the third belt-type conveyor 37 and crushed. The crushed soil of high-quality construction generated soil crushed by the impact crusher 39 is screened by the second vibrating sieve 40 into those having a particle size of 30 mm or more and those having a particle size of 30 mm or less.
The crushed soil of high-quality construction generated soil having a particle size of 30 mm or more screened by the second vibrating screen 40 is crushed again in addition to the impact crusher 39, and the crushed soil of high-quality construction generated soil having a particle size of 30 mm or less. Is added to the second hopper 42 and held by the fifth belt type conveyor 41.
The high-quality construction generated soil having a particle size of 20 mm or less screened by the first vibrating screen 36 is held by the first hopper 43 by the fourth belt type conveyor 38.
The crushed soil of the high-quality construction generated soil of the hopper 42 and the high-quality construction generated soil of the hopper 43 are added to the belt type conveyor 44 and conveyed to the mixer 50. The mixture of the fourth type construction generated soil and lime of the clay soil hopper 24 is added to the belt-type transporting device 44 by the belt-type constant supply device 25 and is transported to the mixing device 50.

Good quality construction generated soil having a particle size of 20 mm or less screened by the mixture of the fourth type construction generated soil and lime held in the cohesive soil hopper 24 and the first vibrating screen held in the first hopper 43 The crushed soil of high-quality construction generated soil having a particle size of 30 mm or less, which is screened by the second vibrating screen 40 held by the second hopper 42, is a belt type transporter 44 in a mass ratio of 5: 3: 2, respectively. Added to.
Lime in the lime silo 15 is screened by the screw type quantitative feeder 17 by the mixture of the fourth type construction generated soil and lime held in the viscous soil hopper 24 and the first vibrating sieve held in the first hopper. The total mass ratio of high-quality construction generated soil with a particle size of 20 mm or less and high-quality construction generated soil with a size of 30 mm or less screened by the second vibrating screen held by the second hopper is about 0.4%. Is added to the belt-type transport machine 44 as a stabilizing material at a ratio of

The cement of the cement silo 18 is screened by the screw type quantitative feeder 19 by the mixture of the fourth type construction generated soil and lime held in the viscous soil hopper 24 and the first vibrating sieve held in the first hopper. The total mass ratio of the high-quality construction generated soil having a particle size of 20 mm or less and the crushed soil of the high-quality construction generated soil having a particle size of 30 mm or less screened by the second vibrating screen retained by the second hopper is about 1 It is added to the belt-type transporter 44 as a stabilizer at a rate of 0.6% and transported to the mixer 50.
Good quality construction generated soil having a particle size of 20 mm or less screened by the mixture of the fourth type construction generated soil and lime held in the cohesive soil hopper 24 and the first vibrating screen held in the first hopper 43 The crushed soil, lime, and cement of high-quality construction generated soil having a particle size of 30 mm or less, which are screened by the second vibrating screen 40 held by the second hopper 42, are mixed by the mixer 50 to produce an improved roadbed material (recycled) )
The improved roadbed material manufactured by the mixer 50 is transported by a belt-type transporter 51 and stored in the stockyard 52 of the improved roadbed material.

Good quality construction generated soil having a particle size of 20 mm or less and second mixed with the mixture of the fourth type construction generated soil and lime held in the cohesive soil hopper and the first vibrating screen held in the first hopper The crushed soil of high-quality construction generated soil having a particle size of 30 mm or less, which is screened by the second vibrating screen held by the hopper, is mixed with the mixer 50 by the belt-type transporter 44 at a mass ratio of 5: 3: 2. Supplied.
In addition, the 4th type construction generated soil and lime mixture held in the viscous soil hopper and the high quality construction generated soil having a particle size of 20 mm or less screened by the first vibrating screen held in the first hopper In the total mass ratio of crushed soil of good quality construction generated soil having a particle size of 30 mm or less screened by the second vibrating screen held by the second hopper, about 1.6% cement and about 0.4% The improved roadbed material is manufactured (regenerated) by mixing lime with a stabilizer 50 with the mixer 50.
The improved roadbed material produced by the mixer 50 is transported by a belt-type transporter 51 that transports it, and stored in a stockyard 52 of the improved roadbed material. The improved roadbed material stored in the stockyard 52 has the same properties as a general roadbed material having improved particle properties and a particle size of 40 mm or less, and can be used as a roadbed material. In addition to this, it is possible to produce (recycle) improved pipe protective material (improved recycled sand) and improved roadbed material by processing this.

Operation | movement of the plant part 60 for manufacturing an improved pipe protection material (improved reproduction | regeneration sand) using an improved roadbed material as a raw material is demonstrated.
The improved roadbed material of the stockyard 52 is thrown into the hopper 62 by the thrower 61.
The improved road bed material of the hopper 62 is added to the vibrating screen 65 by the belt type conveyor 64 that is sent out by the belt type quantitative feeder 63 and conveys the improved road bed material, and those having a particle size of 7-40 mm and those of 7 mm or less. They are screened and stored in stock yard 66.67.
An improved roadbed material having a stock yard 66 having a particle size of 7 mm or less is used as an improved pipe protective material.
Operation | movement of the plant part 70 for manufacturing an improved roadbed material from an improved roadbed material as a raw material is demonstrated.
The improved roadbed material having a stock yard 66 having a particle size of 7 mm or less is charged into the hopper 72 by the charging machine 71. The improved roadbed material having a stock yard 67 having a particle size of 7 to 40 mm is put into the hopper 74 by the feeding machine 71. The improved roadbed material in which the particle size of the hopper 72 is 7 mm or less and the improved roadbed material in which the particle size of the hopper 74 is 7 to 40 mm are respectively sent out at a predetermined ratio by a belt-type fixed amount feeder 73.75. 76 is added to the mixer 77 and mixed to produce a roadbed material.
Since the particle size of the roadbed material can be adjusted by changing the mixing ratio of the improved roadbed material with a hopper 72 particle size of 7 mm or less and the improved roadbed material with a hopper 74 particle size of 7-40 mm, the upper layer roadbed It is possible to manufacture an improved roadbed material having predetermined characteristics of the material and the lower layer roadbed material.
The improved roadbed material mixed and manufactured by the mixer 77 is stored in the stock yard 78.

Next, the principle of the modification of the fourth type construction generated soil performed in the improved plant of the fourth type construction generated soil of the present invention will be described below.
As mentioned above, the fourth type construction generated soil is a soil that cannot be used for backfilling, embankment, etc. as it is, but the reasons for this are as follows. Is large, and the shrinkage due to expansion / drying due to water is large. ”Therefore, the water permeability is low and it can be effectively used only for landfill.
In the present invention, the type 4 construction soil that cannot be effectively used as it is alone is converted from fine-grained to coarse-grained, and the consistency is improved by adding a stabilizer to convert it into an effectively usable soil. It has been modified.
The keywords for particle size conversion and property modification are “mixing of three types” and “crushed soil”. As described above, cohesive soil is an aggregate of fine particles, and its strength is very weak. On the other hand, its characteristics include water retention performance (moisture retention) and density increase due to filling the voids between the soil particles because of fine particles. Therefore, the strength is increased by improving the physical properties by setting the soil particles of various sizes within the specified particle size range (maximum particle size 40 mm) to an appropriate blending fraction (target average particle size 2 to 5 mm). Next, regarding the crushed soil, in the case of circular particles, the meshing between the soil particles is poor, the voids become large, the change in the degree of saturation during flooding is large, and there is a concern that the strength may be reduced.
Therefore, by crushing circular particles into cubic shapes and square beams, the gaps and voids are reduced by meshing between the soil particles, the density of the entire soil particles is increased, and the strength is increased.
Next, the sieve size of each sieve will be described. First, regarding the rotary sieve of the type 4 construction generated soil, as will be described later, the standard value of the roadbed material is a maximum particle size of 100 mm, but it is generally used in consideration of the workability on site. Since the embankment material to be used has a maximum particle size of 40 mm, in consideration of mechanical burden and sieving efficiency, the second stage is set to 100 mm instead of the second stage. As mentioned above, there was also a crushing effect of the sieving machine, and there was almost no sticky clay mass exceeding 100 mm, and the purpose was to screen mixed gravel (stone).
Secondly, it is expected that most of the good quality construction generated soil will be round, although the sieve of good quality construction generated soil is 20 mm.
As described above, it is important to reduce the circular shape as much as possible, and to make it a cubic shape or a square beam. In particular, the product quality is stabilized by changing the particle diameter inside and outside 20 mm to a cubic shape or a square beam, so that it is 20 mm.
Finally, the crushed soil sieve is 30 mm. This is because there is an item of “maximum particle size of 30 mm or less” as “desirable quality of material used for upper layer roadbed material” defined by Shizuoka Prefecture.

Fig. 2 shows the physical properties of the 3rd type construction soil 3 samples, cohesive soil 1., cohesive soil 2, and cohesive soil 3 found in the suburbs of Hamamatsu City, Shizuoka Prefecture, which are the main raw materials for manufacturing improved roadbed materials. It is the table | surface which showed.
FIG. 3 shows the results of the particle size test (particle size accumulation curve) of the viscous soil 1., the viscous soil 2, and the viscous soil 3 in the table of FIG.
The particle size range (▲ wavy line) of the particle size accumulation curve shown in Fig. 3 is the standard value of the particle size range of roadbed materials in the road earthwork "Retaining Wall Guideline" and "Shizuoka Prefectural Banking Material Handling Standards". 100 mm or less, particle size 4.75 mm sieve passage rate (upper limit) 100% to (lower limit value) 25% and 0.075 mm sieve passage rate (upper limit value) 25% to (lower limit value) 0%.
In addition, regarding the consistency characteristic, it is specified that a plasticity index (PI) of 10 or less is 20% or more of deformed soil CBR, which is an index representing bearing capacity.
The three clay soils are outside the standard grain size range indicated by the wavy line, indicating that they cannot be used as road backfills.
In the present invention, with reference to the standard particle size range indicated by the wavy line in FIG. 3, an improved roadbed material having a particle size adjusted by a combination of three kinds of materials (viscous soil, high-quality soil, crushed soil) was manufactured. .
As a result of several dozen patterns of combinations of three types of materials (viscous soil, good quality soil, crushed soil), the combination of 50% viscous soil: 30% high quality soil: 20% crushed soil is the particle size range, plasticity index and deformed soil CBR It conformed to the specified value. The material blending ratio is blended at a wet (natural water content ratio) mass ratio.

Moreover, the present invention adds a stabilizer that mixes quick lime with ordinary Portland cement as a main material to a material combining three kinds of materials (viscous soil, high-quality soil, and crushed soil). The proportion of stabilizer added was 80% normal Portland cement: 20% lime, and 2% added to the mass of all materials became the specified value.
Next, the characteristics of various stabilizers are shown. Ordinary Portland cement improves physical properties by reducing the plasticity index due to a decrease in water content, ion exchange, agglomeration, etc. due to addition, and the strength increases as the hydration reaction of the cement proceeds. A pozzolanic reaction occurs at the age, and a stable strength improvement is performed. Quick lime reacts with quick lime and water by the hydration reaction, moisture evaporates due to the heat of the hydration reaction, and the moisture content decreases. By the pozzolanic reaction, quick lime reacts with alumina and silicon in the earth and sand to form calcium carbonate, increasing the strength of the soil. By ion exchange reaction, fine clay particles are aggregated to make it easier to compact the soil.
Since various effects are obtained, the characteristics are greatly improved. The effect of a stabilizer that mixes quick lime with ordinary Portland cement as the main material is to improve the stable strength by the hydration reaction of normal Portland cement and to reduce the water content due to the evaporation of moisture by the heat of hydration reaction of quick lime. It is a thing.

Fig. 4 shows the ratio of clay (50%): high quality soil (30%): crushed soil (20%) to ordinary material, with the ratio of ordinary Portland cement 80%: quick lime 20%. The results of the physical property test of the improved roadbed material 40-0 mm3 sample produced by adding 2%.
FIG. 5 shows the results of the particle size test (particle size accumulation curve) of the improved roadbed material 40-0 mm3 sample in the table of FIG.
All of the improved roadbed material 40-0mm3 samples are within the standard particle size range of road earthwork “retaining wall guideline”, Shizuoka Prefecture embankment material handling standard (roadbed material standard) indicated by the wavy line, and buried for road It shows that it can be used as a return material.
FIG. 6 is a table showing a comparison of consistency characteristics between only the fourth type construction generated soil and the improved roadbed material of the present invention, and the fourth type construction generated soil 3 sample and the improved roadbed material 3 of the present invention. The comparison of the measured value of the consistency characteristic of a sample is shown.
Regarding consistency characteristics, the standard value of plasticity index (PI) is required to be 10 or less for use as a roadbed material, but as shown in the table of FIG. In the case of cohesive soil alone, the plasticity index (PI) becomes 10 or more, and it cannot be used as a roadbed material. The improved roadbed material of the present invention has a plasticity index (PI) of 10 or less and can be used as a roadbed material.
FIG. 7 is a table showing measured values of the deformed soil CBR of the strength characteristics of the fourth type construction generated soil 3 sample and the improved roadbed material 3 sample of the present invention.
Regarding the strength characteristics, the standard value of deformed soil CBR is 20% or more. However, as shown in the table of Fig. 7, in the case of only type 4 construction generated soil, the standard value of deformed soil CBR of 20% or more is far below. Therefore, it cannot be used as a roadbed material. The improved roadbed material of the present invention greatly exceeds the deformed soil CBR of 20% or more, and can be used as a roadbed material.
Based on the various data as described above, the improved roadbed material manufactured by the improved plant of the fourth type construction generated soil of the present invention cleared the standards of Shizuoka Prefecture due to the above characteristics.

As is clear from the above explanation, the fourth type construction generated soil improvement plant of the present invention reforms and improves all construction generated soil generated by road construction and water and sewage works, etc. If the properties are up to the soil, it can be recycled into products (from the upper-layer roadbed material to the pipe protection material), and an environment-friendly 100% circulating construction-generated soil reclamation system can be realized.
According to the present invention, the fourth type construction soil that causes environmental destruction has been improved to be equal to or higher than conventional crushed stones, etc. so that it can be recycled. Contributes to the prevention of natural destruction and resource depletion, and also helps to compensate for a serious shortage of treatment plants. In addition, since the transportation cost of construction generated soil is saved, it is possible to simultaneously solve various problems occurring with the current road construction.

The present invention can be used in construction industries such as roads, waterworks, and sewers.

It is a figure which shows the structure of the improvement plant of the construction generation soil which mainly made the 4th type construction generation soil of this invention. It is a table showing the physical properties of the 3rd kind construction soil 3 samples, cohesive soil 1., cohesive soil 2, and cohesive soil 3 near Hamamatsu City, Shizuoka Prefecture, which are the main raw materials for producing improved roadbed materials . The execution result of the particle size test (particle size accumulation curve) of three samples of the table | surface of FIG. 2, the clay soil 1, the clay soil 2, and the clay soil 3 is shown. Modified roadbed material manufactured by adding 2% to the total mass ratio of the combination of cohesive soil 5: high quality soil 3: crushed soil 2 in the ratio of ordinary Portland cement 80%: quick lime 20%, physical properties of 3 samples It is the table | surface which showed. The execution result of the particle size test (particle size accumulation curve) of three improved roadbed materials of the table | surface of FIG. 4 is shown. It is the table | surface which showed the comparison of the consistency characteristic of only the 4th type construction generation | occurrence | production soil and the improved roadbed material of this invention. It is the table | surface which showed the comparison of the strength characteristic of only the 4th type construction generation | occurrence | production soil, and the improved roadbed material of this invention.

Explanation of symbols

10 ... Raw material yard for fourth-generation construction generated soil 11 ... Fourth-type construction generated soil charging machine 12 ... Viscous soil hopper 13 into which fourth-type construction generated soil is charged 13 ... Viscous soil hopper Belt type fixed supply machine 14 for sending out 12th kind construction generated soil ... 1st belt type transport machine 15 ... Lime silo 16.17 ... Lime silo 15 for storing lime of modifier Screw-type metering feeder 18 for sending out lime of the above ... Cement silo 19 for storing the cement of the modifying material ... Screw-type metering feeder 20 for sending the cement of the cement silo 18 ... Rotating sieve 21 ... · Stockyard 22 of the 4th class construction soil and lime mixture of 100mm or more ··· Stockyard 24 of the 4th class construction soil and lime mixture of 40 to 100mm 24 · 4th class construction of 40mm or less Soil and stone Viscous soil hopper 25 for holding a mixture of the above-mentioned belt-type fixed supply machine 30 for delivering a mixture of the generated soil and lime of the fourth type construction soil of the viscous soil hopper 24... High quality construction generated soil (first to third types) Material construction yard 31 of seed construction generation soil) ... High quality construction generation soil (first to third type construction generation soil) input machine 32 ... High quality construction generation soil hopper 33 with fixed sieve ... 120mm Stock yard 34 of the above-mentioned high-quality construction generated soil (type 1 to type 3 construction generated soil)... Belt-type quantitative feeder 35 that sends out the high-quality construction generated soil of the high-quality construction generated soil hopper 32. 1st vibration sieve 37.38.41 which sorts high quality construction generated soil (type 1 to 3 type construction generated soil) into 20 mm or more and 20 mm or less. ..Third, fourth and fifth belt type conveyors 39 ... impact crusher 40 ... second vibrating screen 42 ... second hopper 43 ... first hopper 44 ... belt type conveyor 50 ... mixer 51 ... Belt conveyor 52 ... Improved roadbed stock yard 60 ... Plant part 61 for producing improved pipe protection material using improved roadbed as a raw material ... Improved roadbed feeder 62 ... A hopper 63 into which the improved roadbed material is charged ... A belt-type fixed supply device 64 that sends out the improved roadbed material of the hopper 62 ... A belt-type conveyor 65 that conveys the improved roadbed material ... Vibrating sieve 66... Improved roadbed stock yard 67 having a particle size of 7 mm or less.. Improved roadbed stock yard 70 having a particle size of 7 mm or more... Plant portion 71 for producing a roadbed material. ... Improvement machines for improved roadbed materials in stock yards 66 and 67 72 ... A hopper 73 into which an improved roadbed material with a particle size of 7 mm or less is charged ... A belt-type quantitative feeder 74 for delivering the improved roadbed material of the hopper 72 ... An improved road with a particle size of 7 mm or more The hopper 75 to which the floor material is thrown--the belt-type fixed amount feeder 76 that sends out the improved roadbed material of the hopper 74... The belt that conveys the improved roadbed material that is sent from the belt-type fixed amount feeder 73.75 -Type conveyor 77 ... Mixer 78 ... Improved base material stockyard

Claims (4)

Add 1% lime in mass ratio to the 4th construction construction soil (cohesive soil and equivalent), mix,
This mixture is screened into those having a particle size of 100 mm or more, those having a particle size in the range of 100 mm-40 mm, and those having a particle size of 40 mm or less.
Hold the mixture with a screened particle size of 40 mm or less,
The high quality construction generated soil from which the particle size of 120 mm or more is removed from the first to third type construction generated soil (hereinafter referred to as high quality construction generated soil) is screened into those having a particle size of 20 mm or more and 20 mm or less. ,
The high quality construction generated soil having a screened particle size of 20 mm or more is crushed and screened into one having a particle size of 30 mm or more and 30 mm or less,
Hold the crushed soil of the good quality construction generated soil having a screened particle size of 20 mm or less and the good quality construction generated soil having a particle size of 30 mm or less,
A mixture of type 4 construction generated soil having a screened particle size of 40 mm or less and lime, high quality construction generated soil of 20 mm or less screened by sieving, and crushed soil of high quality construction generated soil of 30 mm or less screened Mixing at a mass ratio of 5: 3: 2.
A mixture of Type 4 construction generated soil with a screened particle size of 40 mm or less and lime, a mixture of high quality construction generated soil of 20 mm or less screened by sieving, and a crushed soil of high quality construction generated soil of 30 mm or less screened. Improvement of construction soil mainly composed of type 4 construction soil characterized by mixing 1.6% cement and about 0.4% lime as stabilizer. Method. Means to add 1% lime in mass ratio to the fourth type construction generated soil (cohesive soil and equivalent),
A rotary sieve that screens the mixture of the fourth type construction generated soil and lime into one having a particle size of 100 mm or more, one in the range of 100 mm-40 mm, and one having 40 mm or less,
A cohesive soil hopper holding a mixture of fourth-generation construction generated soil and lime having a particle size of 40 mm or less screened by the rotary sieve;
A fixed sieve that removes soil with a particle size of 120 mm or more from Type 1 to Type 3 construction generated soil (hereinafter referred to as high quality construction generated soil),
A first vibration sieve that screens high-quality construction-generated soil from which particles having a particle size of 120 mm or more have been removed into those having a particle size of 20 mm or more and 20 mm or less;
An impact-type crusher that crushes high-quality construction generated soil having a particle size of 20 mm or more screened by the first vibrating screen,
A second vibrating screen that screens high quality construction generated soil crushed by the impact type crusher into one having a particle size of 30 mm or more and 30 mm or less,
A first hopper that holds high-quality construction generated soil having a particle size of 20 mm or less screened by the first vibrating screen;
Means for crushing the crushed soil of high-quality construction generated soil having a particle size of 30 mm or more screened by the second vibration sieve again to the impact crusher,
A second hopper holding crushed soil of good quality construction generated soil having a particle size of 30 mm or less screened by the second vibrating screen,
4th class construction generated soil and lime mixture held in a cohesive soil hopper, and high quality construction generated soil of 20mm or less screened by the first vibrating screen held in the first hopper and held in the second hopper Means for supplying to the mixer a mass ratio of 5: 3: 2 crushed soil of high quality construction generated soil of 30 mm or less screened by the second vibrating screen,
4th class construction generated soil and lime mixture held in a cohesive soil hopper, and high quality construction generated soil of 20mm or less screened by the first vibrating screen held in the first hopper and held in the second hopper Supplying 1.6% cement and 0.4% lime as stabilizers to the blender at a total mass ratio of crushed soil of good quality construction generated soil of 30mm or less screened by the second vibrating screen Means to regenerate the improved roadbed material,
Construction soil improvement plant mainly composed of Type 4 construction soil. 3. The improved roadbed material according to claim 2, comprising a 7 mm vibrating screen that screens the regenerated improved roadbed material into one having a particle size of 7-40 mm and one having a particle size of 7 mm or less. An improved plant for construction generated soil mainly composed of Type 4 construction generated soil, which is regenerated as improved recycled sand that can be used as a pipe protection material. In Claim 2, the 7mm vibration sieve which screens the improved improved roadbed material into a thing with a particle size of 7-40mm and a thing below 7mm,
A mixer that mixes the improved roadbed material having a particle diameter of 7 mm or less (improved pipe protecting material) and the improved roadbed material having a particle diameter of 7-40 mm, which are screened by the 7 mm vibrating screen, at a predetermined ratio;
A plant for improving construction generated soil mainly composed of type 4 construction generated soil, which is regenerated as roadbed material.

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