CN113196906A

CN113196906A - In-situ quick curing method for raw soil

Info

Publication number: CN113196906A
Application number: CN202110393737.4A
Authority: CN
Inventors: 周建强; 方海兰; 金一鸣; 张敬沙; 商侃侃; 彭红玲; 吕高明; 朱爱娜; 李鸣; 黄伟
Original assignee: Shanghai Greenland Environmental Technology Group Co ltd
Current assignee: Shanghai Construction Engineering Environmental Technology Co ltd
Priority date: 2021-04-13
Filing date: 2021-04-13
Publication date: 2021-08-03
Anticipated expiration: 2041-04-13
Also published as: CN113196906B

Abstract

The invention discloses a method for in-situ rapid curing of raw soil. The method comprises the following steps: firstly, raw soil index detection is carried out to determine the texture type of raw soil, wherein the method for curing clay/sandy soil raw soil comprises the steps of bottom soil structure construction, core soil structure construction, surface soil structure construction and surface soil curing; the method for curing the raw soil of the soil/clay loam comprises the steps of soil leveling and surface soil curing. According to the method, clay soil testing and sand mixing and sandy soil testing and sand control are carried out by accurately measuring the composition of soil particles, so that the method is suitable for raw soil curing of various texture types, and is wide in application range; the particle composition in the improved soil is accurately controlled, the soil texture is fundamentally reconstructed, and the problems of soil hardening, compaction, poor permeability, poor water and fertilizer retention capability and the like are solved.

Description

In-situ quick curing method for raw soil

Technical Field

The invention relates to a method for quickly curing raw soil in situ, belonging to the technical field of soil remediation.

Background

The raw soil refers to 'soil' which is not cultivated by human beings or matured by natural force, is widely existed in coastal reclamation beach areas, urban construction excavation areas, newly-maintained farmlands and natural desertification areas, has the defects of poor soil texture, poor nutrient, acidification or salinization, weak microbial activity and the like, and is not suitable for normal growth of crops. At present, technical measures such as applying soil conditioners, organic fertilizers and returning straws to the field are mainly adopted for raw soil curing, and soil tilth and fertility are continuously improved through cultivation for years.

The traditional curing method has the following defects: firstly, the time consumption is long, namely three or five years for short time and ten or more years for long time; secondly, the soil structure improvement effect is not ideal, for the soil with high viscosity and serious desertification, only the soil fertility is increased, organic fertilizer is applied, the straw is returned to the field, and the like, although the physical structure of the soil can be improved in a short period, the texture of the soil cannot be fundamentally changed; thirdly, only surface soil improvement is carried out, a complete soil layer structure is not formed, the conditions of sand return/stickiness return or nutrient loss and the like caused by the upward movement of lower-layer raw soil are easy to occur, the cured soil is degraded again, and the long-term growth of perennial plants is not facilitated; and fourthly, a quantitative and precise improvement technology is lacked, the curing measures are based on experience, the pertinence is not strong, and the efficiency is low.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the existing raw soil curing method has the problems of long time consumption, unsatisfactory effect on improving the soil structure, incomplete soil layer structure and the like.

In order to solve the technical problems, the invention provides a method for in-situ quick curing of raw soil, which comprises the steps of firstly detecting raw soil indexes to determine the texture type of the raw soil, wherein the method for curing the clay/sandy soil raw soil comprises the steps of constructing a bottom soil structure, constructing a core soil structure, constructing a surface soil structure and curing the surface soil; the method for curing the raw soil of the soil/clay loam comprises the steps of soil leveling and surface soil curing.

Furthermore, the raw soil index detection comprises the detection of soil texture (particle composition) and physical and chemical indexes (pH, salt, organic matters, nitrogen, phosphorus and potassium); the raw soil particle composition was determined by a straw method or a densitometer method and classified according to the international classification standards for soil texture as shown in table 1.

TABLE 1 International soil texture Classification

Further, the construction of the bottom soil structure comprises land leveling, ditching and sand laying/mud filling; the slope drop after land leveling is less than 1/300; the ditching width is 10-20m, the length is 100-200m, the depth is 0.6-1m, and an interval synchronous alternate ditching mode is adopted, namely, the raw soil regions are divided into strips with the same size and are numbered sequentially, odd-numbered strips are excavated firstly, and the excavated raw soil is stacked in adjacent even-numbered strips, so that the subsequent soil recovery is facilitated; paving 10-20cm of yellow sand at the bottom of the ditch for the raw soil with the texture type of clay, wherein the proportion of the particle size of the yellow sand in the range of 0.4-1 mm is not lower than 60%; raw soil with the texture type of sandy soil is poured into the ditch bottom for 5-10 cm (after solidification), and the poured mud can be directly filled with river bottom mud or muddy water is settled for multiple times.

Furthermore, the core-layer soil structure construction comprises soil returning and sand paving/mud filling, and is divided into clay core-layer soil structure construction and sand core-layer soil structure construction according to the texture type of raw soil, and after construction, the content of clay grains in the core-layer structure is lower than 25%, and the content of sand grains is lower than 55%.

Furthermore, the clay core layer soil structure construction comprises soil reclamation and sand paving, the soil reclamation height is 10-20cm, and the sand paving height L_SandAccording to the water content K of sand_SandSand volume weight A_SandAnd the height L of backfilled raw soil_{Raw material}Volume weight A_{Raw material}Clay content N_{Raw material}Sand content S_{Raw material}Water content K_{Raw material}It was determined that the content of agglomerates in the core structure was below 25% and the sand content below 55%, calculated as follows:

furthermore, the sandy soil core layer soil structure construction comprises soil return and mud filling, the soil return height is 10-20cm, and the mud filling height L_MudAccording to the water content K of the irrigation mud_MudVolume weight A_MudContent of clay in mud N_MudSand content S_MudAnd the height L of backfilled raw soil_{Raw material}Volume weight A_{Raw material}Clay content N_{Raw material}Sand content S_{Raw material}Water content K_{Raw material}It was determined that the sand content in the core structure was less than 55% and the grit content less than 25%, calculated as follows:

further, the clay-like surface layer soil structure construction comprises soil returning, airing, plowing and sand paving, and the thickness of the soil returning and the sand paving is the same as that of the clay-like core layer soil structure construction.

Further, the sandy soil surface soil structure construction comprises soil returning, mud filling, airing and turning, the thickness of the soil returning and mud filling is the same as that of a sandy soil core soil structure, a disc plough is used for turning the mud filling layer, the mud filling layer is aired for 1-3 days according to the humidity and weather conditions of the mud filling layer, the turning and airing are repeated for 2-3 times until the mud filling layer is not caked, the water content is preferably 20-25%, and the maximum particle size is less than 10 cm;

further, the surface soil curing comprises paving organic improving materials, adding an acid-base regulator, a soil curing agent and a compound microbial inoculum, turning and airing by a disc plough, crushing and airing by a rotary cultivator, crushing and stirring by a stable soil stirring machine, planting leguminous plants and returning the harvested straws as the organic improving materials to the field before pod formation.

Furthermore, the organic improved material is a product obtained by crushing and harmlessly treating agricultural straws (including straws harvested before leguminous plant planting and pod setting), greening waste and food plant source waste, wherein the product indexes of the crushed and harmlessly treated greening waste and food plant source waste meet the requirements of greening plant waste disposal and application technical code GB/T31755 and 2015, and the paving thickness is 10-30% of the surface soil structure.

Furthermore, the acid-base regulator depends on the acidity and alkalinity of raw soil, the acid raw soil acid-base regulator is an alkaline improved material such as lime, the alkaline raw soil acid-base regulator is an acidic improved material such as wood vinegar and citric acid, and the alkaline raw soil acid-base regulator is preferably applied for a plurality of times in a small amount until the pH value of surface soil reaches 6.5-7.5.

Furthermore, the soil curing agent is prepared from polyacrylamide, a phosphorus-potassium compound fertilizer (potassium hydrogen phosphate for acid soil and potassium dihydrogen phosphate for alkaline soil), potassium fulvate and ammonium bicarbonate according to a mass ratio of 1: 1: 2: 2, and the dosage of each mu is 50-100 kg.

Furthermore, the composite microbial inoculum is prepared from lactic acid bacteria, yeast, bacillus and actinomycetes according to the volume ratio of 1: 1: 1: 1, the effective viable count is more than 2 hundred million/g, and the dosage per mu is 2-3 kg.

Further, the disc plough is ploughed and aired, the ploughing depth is up to the bottom of surface soil, a soil returning layer and a sand/mud filling layer of the surface soil are uniformly mixed with an organic improving material, an acid-base regulator, a soil curing agent and a compound microbial inoculum, the soil is aired for 1-3 days according to the soil humidity and weather conditions, and the ploughing and airing are repeated until the soil is not caked (the maximum particle size is less than 10 cm).

Furthermore, the rotary cultivator is crushed and aired, the rotary tillage depth is consistent with the rotary tillage depth of the disc plough, soil blocks are further crushed, the components are further uniformly mixed, and the rotary cultivator is repeatedly crushed and aired for 2-3 times until the particle size of soil is less than 8 cm.

Furthermore, the stabilized soil mixing machine is used for crushing and mixing, the operation depth is consistent with the rotary tillage depth, and the crushing and mixing are repeated until the particle size of the soil is less than 5 cm.

Further, the legume plants are preferably herbaceous legumes of large biomass.

Furthermore, the harvesting of the straws before podding is that the harvester directly crushes the straws, plows the surface soil once every 1-2 weeks, and seeds of the next batch of leguminous plants are sown after 4-6 weeks.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the method, clay soil testing and sand mixing and sandy soil testing and sand control are carried out by accurately measuring the composition of soil particles, so that the method is suitable for raw soil curing of various texture types, and is wide in application range; the particle composition in the improved soil is accurately controlled, the soil texture is fundamentally reconstructed, and the problems of soil hardening, compaction, poor permeability, poor water and fertilizer retention capability and the like are solved;

2. the invention is different from the traditional soil which is only limited to the surface layer, but is constructed from the whole soil layer, and the soil layers are respectively and comprehensively constructed from three layers of a bottom soil layer, a core soil layer and a surface soil layer, so that the sand return or re-adhesion caused by incomplete improvement of the traditional surface soil is avoided, and the thickness of each layer of soil return and sand laying/mud filling is accurately calculated according to the specific indexes of raw soil and sand laying/mud filling, thereby being scientific and reasonable and constructing a complete soil layer structure;

3. the surface soil of the invention ensures the uniform mixing of all components and ensures the improvement and curing effects through a plurality of cultivation measures such as turning over by a disc plough, crushing by a rotary cultivator, crushing and mixing by a stabilized soil mixer and the like;

4. according to the invention, leguminous plants are planted in the surface soil, the nitrogen fixation effect of the leguminous plants is fully utilized, the harvesting time is strictly controlled, the leguminous plants are smashed and directly turned into the soil before the leguminous plant rhizobia grows into but does not form pods, and meanwhile, the microbial agent is added to accelerate the decomposition of straws; the surface soil is ploughed once every 1-2 weeks, the next batch of leguminous plants is sowed after 4-6 weeks, the leguminous plant planting and the returning of straws to the field before pods are repeatedly carried out, the soil can be cured 2-4 times every year, and the soil curing time can be obviously shortened and the improvement cost can be reduced after 2-3 years.

Drawings

FIG. 1 is a schematic flow chart of the method for in-situ rapid curing of raw soil according to the present invention.

FIG. 2 is a graph showing the soil ripening result of clay;

FIG. 3 is a graph showing the soil ripening result;

reference numerals: 11. a layer of organic modifying material; 12. a surface layer soil sand layer; 13. a surface native soil layer; 21. a core soil sand layer; 22. a core layer original soil layer; 31. a bottom layer soil sand layer; 32. a bottom native layer; 41. a layer of organic modifying material; 42. a surface soil layer; 43. a surface native soil layer; 51. a core soil layer; 52. a core layer original soil layer; 61. a bottom soil layer; 62. the bottom layer is a native soil layer.

Detailed Description

In order to make the invention more comprehensible, preferred embodiments are described in detail below with reference to the accompanying drawings.

Example 1: curing of deep raw soil (clay) for landscaping

The situation of the area to be improved: a large landscaping project, 8000 mu of area, is located on a alluvial island, has short soil forming time, is originally a paddy field, leads to the whole outward transportation or destruction of upper soil in the civil engineering construction in earlier stage, and the planting area soil of planning to afforest is basically the deep soil of continuous form, feels the stickness strong, and the immature soil curing flow is as shown in figure 1, and includes the following steps:

(1) raw soil index detection

Because the regional topography is flat, and soil type is single, will wait to ripen to divide into 48 sample units, adopt chess board method overall arrangement, multiple spot mixed sampling method to take a sample, every 30cm takes a sample, divide 2 layers of samples, soil basicity is strong, salinity content is low, nutrient content is low, the texture is sticky heavy, and specific raw soil index detects as shown in table 2.

TABLE 2 raw soil (clay) index test results

(2) Bottom soil structure construction

According to a specific implementation mode, the working area is divided into a plurality of strips of 20m by 200m, and grooves with the depth of 40cm are alternately formed; the bottom of the ditch is paved with 10cm river sand (the weight ratio of 0.4-1.0mm is 66.0%).

(3) Core soil structure construction

And backfilling 20cm of original soil on the sand layer, and calculating according to a formula that the sand is to be paved by 7.1cm-14.6cm, and finally paving 10cm of sand.

(4) Topsoil structure construction

Backfilling 20cm of raw soil, ploughing by using a disc plough, airing for 2 days, ploughing again, ploughing large soil blocks, and constructing a concentric layer soil structure to lay 10cm of sand.

(5) Curing of surface soil

Spreading compost straw 6cm, scattering 80kg of soil curing agent and 3kg of composite microbial inoculum per mu, diluting 2L of wood vinegar stock solution by 100 times, and spraying on the surface; turning by a disc plough, airing, rotary tillage by a rotary cultivator, crushing by a stabilized soil mixer and mixing.

(6) Leguminous plant planting

Mixing alfalfa and rhizobia according to the weight ratio of 10: 1, sowing according to the sowing amount of 1 kg/mu after mixing, then slightly flattening by using a fence (the depth is not too deep when attention is paid), and then carrying out conventional watering and fertilizing management.

(7) Straw harvesting and returning to field

After the alfalfa grows to 30-50cm (before flowering), the alfalfa is crushed by a harvester and then is dried for 2-3 days, after 80kg of soil curing agent and 3kg of compound microbial inoculum are scattered per mu (the soil curing agent is not scattered after 2 stubbles), 2L of wood vinegar stock solution is diluted by 100 times and then is sprayed on the surface (the wood vinegar dosage is adjusted according to the soil pH condition). The soil was matured 2 years after 2 crops were planted each year, and the results are shown in fig. 2.

Example 2: curing of raw soil (sandy soil) of farmland at certain mud flat

The situation of the area to be improved: the soil is formed by sedimentation of river silt and is positioned on the mud flat of the yellow river, pebbles, broken stones and soil are mixed under the shallow soil layer, and the sand content is high.

(1) Raw soil index detection

The areas are distributed along the river in a strip shape, the topography is slightly inclined towards one side of the river channel, the area to be improved is divided into sampling units every 500m along the river flow direction, sampling is carried out by adopting a snake-shaped method layout and a multipoint mixed sampling method, one sample is taken every 30cm, sampling is carried out in 2 layers, the soil is strong in alkalinity, low in salinity, low in partial nutrient content and high in soil sand content, and specific raw soil index detection results are shown in table 3.

TABLE 3 raw soil (sandy soil) index test results

(2) Bottom soil structure construction

According to a specific implementation mode, the working area is divided into a plurality of strips of 15m by 100m, and grooves with the depth of 30cm are alternately formed; and (5) paving 10cm of pond sludge at the bottom of the ditch.

(3) Core soil structure construction

And backfilling 15cm of original soil on the mud layer, and calculating according to a formula that sand is paved by 4.1cm-8.6cm, wherein the final height of the pond mud is 5 cm.

(4) Topsoil structure construction

Backfilling raw soil 15cm, airing the pond sludge 5cm later for 3 days, ploughing by using a disc plough, airing again for 2 days, and ploughing.

(5) Curing of surface soil

Spreading composted straws 4cm, scattering 50kg of soil curing agent and 3kg of composite microbial inoculum per mu, diluting 1L of wood vinegar stock solution by 100 times, and spraying on the surface; turning by a disc plough, airing, rotary tillage by a rotary cultivator, crushing by a stabilized soil mixer and mixing.

(6) Leguminous plant planting

(7) Straw harvesting and returning to field

After the alfalfa grows to 30-50cm (before flowering), the alfalfa is crushed by a harvester and then is dried for 2-3 days, 50kg of soil curing agent and 3kg of composite microbial inoculum are scattered per mu (the soil curing agent is not scattered after 2 crops), 0.5L of wood vinegar stock solution is diluted by 100 times and then is sprayed on the surface (the amount of the wood vinegar is adjusted according to the pH condition of the soil). The soil was matured 2 years after 2 crops were planted each year, and the results are shown in fig. 3.

The above-described embodiments are only preferred embodiments of the present invention, and are not intended to limit the present invention in any way and substantially, it should be noted that those skilled in the art may make several modifications and additions without departing from the scope of the present invention, which should also be construed as a protection scope of the present invention.

Claims

1. The method for in-situ rapid curing of raw soil is characterized by comprising the steps of firstly detecting raw soil indexes to determine the texture type of the raw soil, wherein the method for curing clay/sandy soil raw soil comprises the steps of constructing a bottom soil structure, constructing a core soil structure, constructing a surface soil structure and curing surface soil; the method for curing the raw soil of the soil/clay loam comprises the steps of soil leveling and surface soil curing.

2. The method for in-situ rapid curing of raw soil according to claim 1, wherein the raw soil index detection comprises detection of particle composition and physicochemical index of raw soil.

3. The method of claim 1, wherein the sub-soil structure construction comprises land leveling, trenching and sanding/drenching.

4. The method for in situ rapid maturation of subsoil as claimed in claim 1, wherein said core soil structure construction comprises soil return and sand/mud laying.

5. The method for in-situ rapid curing of raw soil according to claim 1, wherein the topsoil structure construction is divided into two types according to the texture type of raw soil, wherein the clay type topsoil structure construction comprises soil returning, airing, plowing and sand spreading, and the sandy type topsoil structure construction comprises soil returning, mud filling, airing and plowing.

6. The method for in-situ rapid curing of raw soil according to claim 1, wherein the curing of surface soil comprises spreading organic modifying materials, adding acid-base regulator, soil curing agent and complex microbial inoculum, turning and airing by disc plough, crushing and airing by rotary cultivator, crushing and stirring by stable soil stirrer, planting leguminous plants and returning the harvested straws as organic modifying materials to field.

7. The method for in-situ rapid curing of raw soil according to claim 4 or 5, wherein the thickness L of the spread sand is_SandComprises the following steps:

wherein, K_SandWater content of sand, A_SandIs the volume weight of sand, L_{Raw material}For backfilling the height of the raw soil, A_{Raw material}For backfilling the volume weight, N of raw soil_{Raw material}The clay content, S, of the backfilled raw soil_{Raw material}Sand grain content, K, for backfilling raw soil_{Raw material}The water content of the backfilled raw soil.

8. The method for in-situ rapid curing of raw soil according to claim 4 or 5, wherein the thickness L of the grouting mud_MudComprises the following steps:

wherein, K_MudFor the water content of the grouting material, A_MudFor the volume weight of the mud, N_MudIs the content of clay particles, S, in the grouting mud_MudIs the sand content in the grouting mud, L_{Raw material}To backfill the height of the raw soil, A_{Raw material}Is the volume weight of backfilled raw soil, N_{Raw material}Is the clay content of backfilled raw soil, S_{Raw material}Sand content of backfilled raw soil, K_{Raw material}And determining the water content of the backfilled raw soil.