CN117296673A - Ecological restoration matrix and application method thereof - Google Patents

Abstract

The invention provides an ecological restoration matrix, which comprises 3 layers from bottom to top, namely an A reinforcing restoration layer, a B nutrition layer and a C crust layer; the A layer composition comprises cement, quartz stone, waste glass particles, medium sand, waste glass powder, perlite powder, sewage sludge biochar, a water reducing agent and water; the B layer composition comprises cement, waste glass particle perlite particle mixture, sewage sludge biochar, soil and water; the layer C contains algae moss mixture and guar gum. The ecological restoration matrix provided by the invention is used for mines and highway slopes, can quickly restore ecological environment, improve soil, is suitable for various vegetation, reduces water and soil loss, is environment-friendly and effectively avoids environmental pollution.

Description

Ecological restoration matrix and application method thereof

Technical Field

The invention relates to an ecological matrix, in particular to an ecological restoration matrix suitable for mines and highway slopes.

Background

The problems of highway slope destruction and collapse are major threats, some highway foundations are formed by the fact that vegetation cannot be planted on rocks, and heavy rain flushing causes water and soil loss and heavy metal pollution, and the ecological restoration of the highway slopes can be affected by the problems.

The existing ecological restoration matrix is basically prepared by paving soil on bare rock to plant vegetation, has long period and high requirement on the vegetation, and simultaneously has no attention on heavy metal pollution, water and soil loss and environmental protection.

Disclosure of Invention

In view of the above-described deficiencies in the prior art, the present invention provides an ecological restoration matrix and methods of use thereof. The ecological restoration matrix provided by the invention can be used for ecological restoration of mines and highway slopes.

Specifically, the invention is realized by the following technical scheme:

an ecological restoration matrix is characterized in that 3 layers are respectively an A reinforcing restoration layer, a B nutrition layer and a C crust layer from inside to outside. The A layer comprises cement, quartz stone, waste glass particles, middle sand, waste glass powder, perlite powder, sewage sludge biochar, a water reducer and water, wherein the weight ratio of the cement to the quartz stone to the middle sand to the water reducer is 2:6:3:0.01, the weight ratio of the waste glass particles to the quartz stone is 1:4-19, the weight ratio of the perlite powder to the waste glass powder to the middle sand is 1:3:16-36, the weight ratio of the cement to the sewage sludge biochar is 100:1-10, and the water-cement ratio is 0.3-0.5. The B layer comprises cement, a waste glass particle perlite particle mixture, sewage sludge biochar, soil and water, wherein the weight ratio of the cement to the waste glass particle perlite particle mixture to the soil to the water is 1 (1.5-2) 10:1, the weight ratio of the waste glass particles to the perlite particles in the waste glass particle perlite particle mixture is 2:1, and the weight ratio of the sewage sludge biochar to the soil is 1 (3-10). The layer C contains algae moss mixture and guar gum, the dry weight ratio of algae to moss in the algae moss mixture is 1:2, the coverage rate of the algae moss mixture in each square meter area is 0.05-0.1m < 2 >, and the dry weight of the guar gum in each square meter area is 1-5g.

Wherein, the diameter of the waste glass particles is 3-10mm, the diameter of the waste glass powder is less than 0.5mm, the diameter of the perlite particles is 0.5-5mm, the diameter of the perlite powder is less than 0.5mm, and the particle size of the sewage sludge biochar is 1-10mm.

Preferably, the algae moss mixture is an algae fragment and moss fragment mixture, wherein the algae fragment is 15-20mm and the moss fragment is 15-20mm.

Preferably, the algal moss mixture is taken from the area to be ecologically restored.

Preferably, the preparation method of the sewage sludge biochar comprises the following steps: (1) Collecting sewage sludge, air-drying, and drying in an oven at 110 ℃ for 24 hours; (2) crushing and grinding the waste glass particles, and passing through a 0.2mm screen; (3) Mixing the dried sewage sludge and the sieved waste glass particles according to the mass ratio of 5:2, carrying out in a pyrolysis reactor under a nitrogen environment, heating at a speed of 5 ℃/min until the temperature reaches 500 ℃, carrying out the whole pyrolysis process for 2 hours, and then sieving with a 2mm sieve.

Preferably, the soil is from sanded soil, abandoned farmland.

Preferably, the method is suitable for ecological restoration of mines and highway slopes.

Preferably, the method of using the ecological restoration matrix comprises the steps of:

(1) Preparing anchors and wire meshes;

(2) And (3) preparing a layer A: fully mixing sewage sludge biochar with water, and then adding cement, quartz stone, waste glass particles, medium sand, waste glass powder, perlite powder and a water reducer into the mixture, and fully and uniformly stirring the mixture;

(3) Checking the whole condition on the slope, removing the barrier, spraying the slope with water, and spraying the layer A with the thickness of 3-6cm.

(4) After hardening of layer a, layer B was prepared: fully mixing sewage sludge biochar with water, then adding cement, waste glass particle perlite particle mixture and soil into the mixture, fully and uniformly stirring the mixture, and spraying the mixture with the thickness of 3-6 cm;

(5) And C, preparing a layer: the guar gum is prepared into 1g/L homogenate by water, the guar gum is sprayed, and then the algae moss mixture is uniformly sown.

The invention has the advantages that: the invention adopts waste glass particles, waste glass powder, sewage sludge biochar and waste soil as matrix ingredients, and has the advantages of obvious effect on the secondary utilization of wastes, no environmental pollution, contribution to sustainable development and environmental protection. The layer A is concrete modified by sewage sludge biochar, and is used as a reinforcing layer to connect bare rock and a nutrition layer, so that on one hand, complex terrains of mines or highway slopes are improved, such as a 'pedal dead zone' is filled, the content of large-particle substances is increased, so that the friction force is increased, the ground grabbing performance of the nutrition layer is improved, on the other hand, the insulation and reserve effects are achieved, the nutrition layer and bare rock are isolated, bare rock harmful substances such as heavy metals are buried, the pH value of the nutrition layer is improved, the nutrition layer is assisted to store moisture and organic substances, certain air circulation is provided through base material proportion, and the like, and the later vegetation is facilitated. The layer B is used as a nutrition layer, adopts sewage sludge biochar to provide organic substances for waste soil, adopts a waste glass particle perlite particle mixture to provide certain water absorption performance, and provides a powerful material foundation for vegetation growth. The layer C is a crust layer, the mixed organisms of algae and moss are artificially accelerated to form crust, a richer nutrition foundation is provided for later-stage vegetation, and the mixed organisms are also a stabilizer of soil to prevent soil loss. The ecological restoration matrix provided by the invention can quickly restore the ecological environment, improve the soil, is suitable for various vegetation and beautifies cities.

Detailed Description

The invention will be further described in detail with reference to the following specific examples, which are given for the purpose of illustration only and are not to be construed as further limiting the invention.

Example 1

An ecological restoration matrix, the base material ratio is shown in the following table 1.

TABLE 1 base stock formulation of ecological restoration matrix

A method of using an ecological restoration substrate comprising the steps of:

(1) Collecting sewage sludge, air-drying, and drying in an oven at 110 ℃ for 24 hours; (2) crushing and grinding the waste glass particles, and passing through a 0.2mm screen; (3) Mixing the dried sewage sludge and the sieved waste glass particles according to the mass ratio of 5:2, carrying out in a pyrolysis reactor under a nitrogen environment, heating at a speed of 5 ℃/min until the temperature reaches 500 ℃, carrying out the whole pyrolysis process for 2 hours, and then sieving the mixture with a 2mm sieve to obtain the sewage sludge biochar.

(2) And (5) arranging anchors and wires.

(3) And (3) preparing a layer A: fully mixing sewage sludge biochar with water, and then adding cement, quartz stone, waste glass particles, medium sand, waste glass powder, perlite powder and a water reducer into the mixture, and fully and uniformly stirring the mixture;

(4) Checking the whole condition on the slope, removing the barrier, spraying the slope with water, and spraying the layer A with the thickness of 5cm.

(5) After hardening of layer a, layer B was prepared: fully mixing sewage sludge biochar with water, then adding cement, waste glass particle perlite particle mixture and abandoned land soil into the mixture, fully and uniformly stirring the mixture, and spraying the mixture with the thickness of 6cm;

(6) And C, preparing a layer: the guar gum is prepared into 1g/L homogenate by water, the guar gum is sprayed, algae and moss which naturally grow are collected from mines and made into fragments, wherein the algae fragments are 15mm, the moss fragments are 15mm, and after mixing, the algae moss mixture is uniformly sown.

Example 2

An ecological restoration matrix, the base material ratio is shown in the following table 2.

TABLE 2 base stock formulation of ecological restoration matrix

A method of using an ecological restoration substrate comprising the steps of:

(1) Collecting sewage sludge, air-drying, and drying in an oven at 110 ℃ for 24 hours; (2) crushing and grinding the waste glass particles, and passing through a 0.2mm screen; (3) Mixing the dried sewage sludge and the sieved waste glass particles according to the mass ratio of 5:2, carrying out in a pyrolysis reactor under a nitrogen environment, heating at a speed of 5 ℃/min until the temperature reaches 500 ℃, carrying out the whole pyrolysis process for 2 hours, and then sieving the mixture with a 2mm sieve to obtain the sewage sludge biochar.

(2) And (5) arranging anchors and wires.

(3) And (3) preparing a layer A: fully mixing sewage sludge biochar with water, and then adding cement, quartz stone, waste glass particles, medium sand, waste glass powder, perlite powder and a water reducer into the mixture, and fully and uniformly stirring the mixture;

(4) Checking the whole condition on the slope, removing the barrier, spraying the slope with water, and spraying the layer A with the thickness of 5cm.

(5) After hardening of layer a, layer B was prepared: fully mixing sewage sludge biochar with water, then adding cement, waste glass particle perlite particle mixture and waste farmland soil into the mixture, fully and uniformly stirring the mixture, and spraying the mixture to a thickness of 6cm;

(6) And C, preparing a layer: the guar gum is prepared into 1g/L homogenate by water, the guar gum is sprayed, algae and moss which naturally grow are collected from mines and made into fragments, wherein the algae fragments are 50mm, the moss fragments are 50mm, and after mixing, the algae moss mixture is uniformly sown.

Example 3

An ecological restoration matrix, the base material ratio is shown in the following table 3.

TABLE 3 base stock formulation of ecological restoration matrix

A method of using an ecological restoration substrate comprising the steps of:

(1) Collecting sewage sludge, air-drying, and drying in an oven at 110 ℃ for 24 hours; (2) crushing and grinding the waste glass particles, and passing through a 0.2mm screen; (3) Mixing the dried sewage sludge and the sieved waste glass particles according to the mass ratio of 5:2, carrying out in a pyrolysis reactor under a nitrogen environment, heating at a speed of 5 ℃/min until the temperature reaches 500 ℃, carrying out the whole pyrolysis process for 2 hours, and then sieving the mixture with a 2mm sieve to obtain the sewage sludge biochar.

(2) And (5) arranging anchors and wires.

(3) And (3) preparing a layer A: fully mixing sewage sludge biochar with water, and then adding cement, quartz stone, waste glass particles, medium sand, waste glass powder, perlite powder and a water reducer into the mixture, and fully and uniformly stirring the mixture;

(4) Checking the whole condition on the slope, removing the barrier, spraying the slope with water, and spraying the layer A with the thickness of 5cm.

(5) After hardening of layer a, layer B was prepared: fully mixing sewage sludge biochar with water, then adding cement, waste glass particle perlite particle mixture and abandoned land soil into the mixture, fully and uniformly stirring the mixture, and spraying the mixture with the thickness of 6cm;

(6) And C, preparing a layer: the guar gum is prepared into 1g/L homogenate by water, the guar gum is sprayed, algae and moss which naturally grow are collected from mines and made into fragments, wherein the algae fragments are 15mm, the moss fragments are 15mm, and after mixing, the algae moss mixture is uniformly sown.

Control group 1

An ecological restoration matrix, the base material ratio is shown in the following table 4.

TABLE 4 base stock formulation of ecological restoration matrix

A method of using an ecological restoration substrate comprising the steps of:

(1) And (5) arranging anchors and wires.

(2) And (3) preparing a layer A: cement, quartz stone, middle sand, water and a water reducing agent are fully and uniformly stirred;

(3) Checking the whole condition on the slope, removing the barrier, spraying the slope with water, and spraying the layer A with the thickness of 5cm.

(4) After hardening of layer a, layer B was prepared: cement, soil of abandoned farmland and water are fully and uniformly stirred and sprayed, and the thickness is 6cm.

Control group 5

The ecological restoration matrix and the base material ratio are shown in the following table 5.

TABLE 5 base stock formulation of ecological restoration matrix

A method of using an ecological restoration substrate comprising the steps of:

(1) Collecting sewage sludge, air-drying, and drying in an oven at 110 ℃ for 24 hours; (2) crushing and grinding the waste glass particles, and passing through a 0.2mm screen; (3) Mixing the dried sewage sludge and the sieved waste glass particles according to the mass ratio of 5:2, carrying out in a pyrolysis reactor under a nitrogen environment, heating at a speed of 5 ℃/min until the temperature reaches 500 ℃, carrying out the whole pyrolysis process for 2 hours, and then sieving the mixture with a 2mm sieve to obtain the sewage sludge biochar.

(2) And (5) arranging anchors and wires.

(3) And (3) preparing a layer A: cement, quartz stone, middle sand, water and a water reducing agent are fully and uniformly stirred;

(4) Checking the whole condition on the slope, removing the barrier, spraying the slope with water, and spraying the layer A with the thickness of 5cm.

(5) After hardening of layer a, layer B was prepared: fully mixing sewage sludge biochar with water, then adding cement, perlite particles and waste farmland soil into the mixture, fully and uniformly stirring the mixture, and spraying the mixture to a thickness of 6cm;

(6) And C, preparing a layer: collecting algae naturally growing in the outside, preparing into fragments, wherein the algae fragments are 15mm, the moss fragments are 15mm, mixing, and then uniformly sowing the algae moss mixture.

Test example 1

The base materials of group A in examples 1-3 and the control group A were used to prepare layer A, and the layer A was poured into a grinding tool, and the compressive strength was measured according to the compressive strength test in GB/T50081-2019 method for testing physical mechanical properties of concrete. The leachate was prepared by referring to the method steps in HJ 557-2010 "horizontal oscillation method for solid waste leaching toxicity leaching method", and the content of Cd, cr, cu, pb, zn in the sample was measured according to GB/T14848-2017 "groundwater quality Standard", and specific experimental data are shown in Table 6 below.

Table 6 performance test

	Intensity (Mpa)	Cd(mg/kg)	Cr(mg/kg)	Cu(mg/kg)	Pb(mg/kg)	Zn(mg/kg)
							Example 1	20.28	0.95	131.56	16.43	12.56	50.11
Example 2	18.33	1.03	134.55	17.23	12.91	52.65
							Example 3	16.32	0.99	138.46	18.55	12.58	51.48
Control group 1	15.98	0.88	125.37	15.1	11.58	48.95

The examples all contain waste glass substances and sewage sludge biochar as dopants, and the compressive strength is larger than that of the control group, but the compressive strength is slightly higher and lower along with different ratios, and as can be seen from examples 1 and 2, the ratio of the waste glass substances is too high, and the compressive strength is reduced. It can be seen from examples 2 and 3 that the content of the sewage sludge biochar also affects the compressive strength.

The sewage sludge is used as waste and has too high heavy metal content, the heavy metal content of the sewage sludge biochar prepared by glass particle catalysis and high-temperature pyrolysis is reduced, but along with the increase of the temperature, the organic substances of the sewage sludge biochar are also obviously reduced, so that the invention adopts 500 ℃ as the optimal pyrolysis temperature, and not only can the heavy metal content of the sewage sludge biochar be reduced, but also the organic substance content is ensured. The waste glass substance also contains a certain amount of heavy metal, but the planting requirement can be met by controlling the content. As can be seen from Table 6, the heavy metal content in each example was slightly greater than that in the control group, but the difference was not great, and the effect on plants was very small, mainly due to the control of the content of each component and the presence of certain heavy metal passivation effect on the sewage sludge biochar.

Test example 2

The base materials of examples 1 to 3 and the base materials of the control groups 1 to 2 were used to prepare the A+B layer, the A+B layer was introduced into a grinding tool, the grinding tool was weighed after drying, 50 times of water was added according to the mass ratio, the mixture was allowed to stand at room temperature for 4 hours, the sample was filtered through a 100-mesh screen until the sample mass was constant, the sample was weighed, and the water absorption was calculated according to the following formula, and the results were shown in Table 7 below.

Water absorption= (weight of sample after water absorption-weight of sample before water absorption)/weight of sample before water absorption

TABLE 7 Water absorbency test

	Water absorption (%)
		Example 1	66.8
Example 2	67.2
		Example 3	63.1
Control group 1	59.5
		Control group 2	60.9

It can be seen from Table 7 that the waste glass particles, waste glass powder, perlite powder in the A layer have an accelerating effect on water absorption as can be seen from examples 1 and 2. It can be seen from examples 2 and 3 that the waste glass particle perlite particle mixture has a significant effect on water absorption, and that excessive amounts reduce soil water absorption.

Test example 3

The mine is divided into 5 areas, and each area ensures similar landforms. The schemes of examples 1-3 and control groups 1-2 were used to restore ecology in each area, 10 points were randomly sampled for each area after 6 months, and the soil organic carbon content, aggregate stability and average value were measured. Ryegrass was randomly sown, 10 points were randomly sampled after 30d, and root length and plant height were measured, and the results are shown in table 8.

Wherein the organic carbon content of the organic carbon soil is detected by adopting a potassium dichromate external heating method.

The agglomerate stability is achieved by wet screening: 50g aggregates of soil samples were carefully immersed in 500mL of water for 10 minutes and then screened with screens of different sizes, the MWD (mean weight diameter) being a parameter derived from the sum of the mass fractions of soil left on each screen after screening.

TABLE 8 vegetation cases

The examples and the control group show that guar gum is used as a plant-derived tackifier, which improves the stability of soil aggregate and effectively accelerates biological skinning, but the content is not too high, otherwise, the plant growth is affected. The embodiment and the control group 2 can show that the artificial biological crust formed in the invention is a mixed type of algae and moss, the local dominant type is more favorable for forming the artificial crust, and the two types cooperate with each other to effectively improve the soil hardness, prevent dust and water, effectively cope with natural disasters and be an efficient soil stabilizer. In the research, the sewage sludge biochar can provide organic substances for soil, and the biological crust is also the same, so that the algae and moss mixture provides more abundant nutritional ingredients. From example 2 it can be seen that the small-fragment algae moss mixture is more favorable for even distribution of biological crust and organic matter.

Claims (7)

1. An ecological restoration matrix is characterized in that 3 layers are respectively an A reinforcing restoration layer, a B nutrition layer and a C crust layer from inside to outside;

the A layer comprises cement, quartz stone, waste glass particles, middle sand, waste glass powder, perlite powder, sewage sludge biochar, a water reducing agent and water, wherein the weight ratio of the cement to the quartz stone to the middle sand to the water reducing agent is 2:6:3:0.01, the weight ratio of the waste glass particles to the quartz stone is 1 (4-19), the weight ratio of the perlite powder to the waste glass powder to the middle sand is 1:3 (16-36), the weight ratio of the cement to the sewage sludge biochar is 100 (1-10), and the water-cement ratio is 0.3-0.5;

the B layer comprises cement, a waste glass particle perlite particle mixture, sewage sludge biochar, soil and water, wherein the weight ratio of the cement to the waste glass particle perlite particle mixture to the soil to the water is 1 (1.5-2) 10:1, the weight ratio of the waste glass particles to the perlite particles in the waste glass particle perlite particle mixture is 2:1, and the weight ratio of the sewage sludge biochar to the soil is 1 (3-10);

the layer C contains an algae moss mixture and guar gum, the dry weight ratio of algae to moss in the algae moss mixture is 1:2, and the coverage rate of the algae moss mixture in each square meter area is 0.05-0.1m ² The dry weight of guar gum in each square meter area is 1-5g;

the diameter of the waste glass particles is 3-10mm, the diameter of the waste glass powder is less than 0.5mm, the diameter of the perlite particles is 0.5-5mm, the diameter of the perlite powder is less than 0.5mm, and the particle size of the sewage sludge biochar is 1-10mm.

2. The ecological restoration substrate according to claim 1, wherein the algae moss mixture is an algae fragment and moss fragment mixture, wherein the algae fragment is 15-20mm and the moss fragment is 15-20mm.

3. The ecological restoration substrate as recited in claim 1, wherein the algal moss mixture is taken from a region to be ecologically restored.

4. The ecological restoration substrate as recited in claim 1, wherein the sewage sludge biochar is prepared by a method comprising: (1) Collecting sewage sludge, air-drying, and drying in an oven at 110 ℃ for 24 hours; (2) crushing and grinding the waste glass particles, and passing through a 0.2mm screen; (3) Mixing the dried sewage sludge and the sieved waste glass particles according to the mass ratio of 5:2, carrying out in a pyrolysis reactor under a nitrogen environment, heating at a speed of 5 ℃/min until the temperature reaches 500 ℃, carrying out the whole pyrolysis process for 2 hours, and then sieving with a 2mm sieve.

5. The ecological restoration substrate according to claim 1, wherein the soil is derived from sanded soil, abandoned farmland.

6. The ecological restoration substrate as set forth in claim 1, being suitable for ecological restoration of mines and highway slopes.

7. The method of using an ecological restoration substrate according to any one of claims 1 to 6, comprising the steps of:

(1) Preparing anchors and wire meshes;

(2) And (3) preparing a layer A: fully mixing sewage sludge biochar with water, and then adding cement, quartz stone, waste glass particles, medium sand, waste glass powder, perlite powder and a water reducer into the mixture, and fully and uniformly stirring the mixture;

(3) Checking the whole condition on the slope, removing the barrier, spraying the slope with water, and spraying the layer A with the thickness of 3-6cm.

(4) After hardening of layer a, layer B was prepared: fully mixing sewage sludge biochar with water, then adding cement, waste glass particle perlite particle mixture and soil into the mixture, fully and uniformly stirring the mixture, and spraying the mixture with the thickness of 3-6 cm;

(5) And C, preparing a layer: the guar gum is prepared into 1g/L homogenate by water, the guar gum is sprayed, and then the algae moss mixture is uniformly sown.