CN113924944A - Three-dimensional potted plant substrate and manufacturing method thereof - Google Patents

Abstract

A three-dimensional potted plant substrate and a manufacturing method thereof. The three-dimensional potted plant substrate comprises 0-25% by volume of crushed grains with the size of more than 15mm, 5-20% by volume of crushed grains with the size of 10-15 mm, 10-20% by volume of crushed grains with the size of 5-10 mm, 15-25% by volume of crushed grains with the size of 1-5 mm and 25-55% by volume of crushed grains with the size of less than 1 mm. The three-dimensional potted plant substrate utilizes various inorganic components and organic components as raw materials, controls the void proportion of the substrate, namely the pore size distribution, by regulating and controlling the particle size fractions with different particle sizes in the substrate, establishes a scientific and reasonable potted plant, namely a container culture substrate, is suitable for supplying moisture, oxygen and nutrition required by various potted plants to the maximum extent, has lighter volume weight, reduces building load, and has the advantages of strong fertilizer and water retention capacity and the like.

Description

Three-dimensional potted plant substrate and manufacturing method thereof

Technical Field

The invention belongs to the technical field of plant growth substrates, and particularly relates to a three-dimensional pot culture substrate and a manufacturing method thereof, which are mainly suitable for container culture substrates for various three-dimensional greening plant pots in the market.

Background

The three-dimensional greening pot culture is arranged in containers such as flowerpots and the like, so the three-dimensional greening pot culture can also be called container pot culture, the three-dimensional greening in China starts for over ten years, so the three-dimensional greening pot culture is relatively lack in plant cultivation research, and the research on a cultivation carrier-matrix required by the three-dimensional greening pot culture in a three-dimensional environment is few and less and is dozens of years behind European America. The three-dimensional greening is an important component part for promoting sponge city construction and ecological city construction in China and is also an indispensable content of a future novel building, namely a fourth generation house, the research on the overall matrix level of China lags behind, the three-dimensional greening always stays at the middle and later stages of the century in Europe and America, belongs to the material proportioning stage, and is not deep enough and lags behind in the research on the radial distribution control. The research on the three-dimensional greening potted substrate, particularly the research on the control of the water-gas configuration is almost zero, so that the establishment of the technical standard of the three-dimensional greening cultivation or container cultivation substrate is always expected in China, and a novel substrate process technology for controlling the pore size distribution through the particle size distribution is expected. The substrate with controllable water-vapor configuration is the basis for improving the overall level of three-dimensional greening.

In order to meet the requirement of improving the overall level of three-dimensional greening in China, a first general technical (group) standard of a three-dimensional greening culture substrate is formulated, and a suitable three-dimensional greening substrate production technology and process are provided according to the standard requirement, so that the significance is great, and the implementation of the three-dimensional greening culture substrate is beneficial to improving the current situation that the three-dimensional greening is lagged for a long time and is difficult to regulate and manage.

Disclosure of Invention

The invention mainly aims to provide a three-dimensional pot culture substrate taking perlite, vermiculite, slag, turf, coconut husk and harmless fermentation products obtained by fermenting planting, breeding and garden wastes as raw materials and a manufacturing method thereof, so as to at least partially solve the technical problems.

In order to achieve the above object, as one aspect of the present invention, there is provided a three-dimensional pot culture substrate and a method for manufacturing the same, wherein the volume percentage of the crushed pieces having a size of more than 15mm size fraction is 0% to 25%, the volume percentage of the crushed pieces having a size of 10mm to 15mm size fraction is 5% to 20%, the volume percentage of the crushed pieces having a size of 5mm to 10mm size fraction is 10% to 20%, the volume percentage of the crushed pieces having a size of 1mm to 5mm size fraction is 15% to 25%, and the volume percentage of the crushed pieces having a size of 1mm size fraction or less is 25% to 55%.

The invention also provides a manufacturing method of the three-dimensional potting matrix, which comprises the following steps of obtaining the three-dimensional potting matrix, wherein the volume percentage of the crushed grains with the size of more than 15mm is 0-25%, the volume percentage of the crushed grains with the size of 10mm-15mm is 5-20%, the volume percentage of the crushed grains with the size of 5mm-10mm is 10-20%, the volume percentage of the crushed grains with the size of 1mm-5mm is 15-25%, and the volume percentage of the crushed grains with the size of less than 1mm is 25-55%.

Based on the technical scheme, compared with the prior art, the matrix material and the preparation method thereof have at least one of the following beneficial effects:

the invention selects the volume percentage ratio of the matrix materials with different grain diameters, so that the porosity of the matrix is proper, the permeability is good, excessive water retention is avoided, and the water, oxygen and nutrition supply of plants is met to the maximum extent;

the invention selects industrial waste components as main materials in the materials of the matrix, thereby enhancing the fertilizer and water retention capacity of the matrix and reducing the times of fertilization and irrigation while saving the economic consumption and achieving the purpose of green environmental protection;

the invention has the advantages that the volume weight of the matrix material is light, the load is reduced, the matrix does not drift along with the wind and the water, and the matrix material can be widely applied to the three-dimensional greening of different buildings.

Drawings

FIG. 1 is a process flow chart of the method for manufacturing the three-dimensional potting medium of the present invention.

FIG. 2 is a flow chart of the process for selecting the granules of the three-dimensional potted substrate of the present invention.

FIG. 3 is a composition diagram of the average distribution of the potted plant substrate particles according to an embodiment of the present invention.

FIG. 4 is a flow chart of a process for making a three-dimensional potting substrate according to an embodiment of the present invention.

Detailed Description

The invention provides a three-dimensional potted plant substrate and a manufacturing method thereof, which are mainly suitable for providing a growth carrier for greening plants on vertical surfaces, sloping surfaces and plane containers among floors of a building body. The three-dimensional greening substrate refers to: the three-dimensional greening substrate can also be understood as a container potting substrate because plants are arranged in a container such as a flowerpot and the like, wherein the inorganic component is selected from inorganic components, preferably substances with small volume weight and good permeability, for example, industrial wastes are used as main raw materials such as slag (crushed), fly ash and vermiculite, silt and the like. The organic component is selected to be at least one of: peat, coconut husk and planting, breeding and garden waste. Setting a particle size ratio intermediate value, wherein when the three-dimensional potted plant is a small plant, the volume percentage of the crushed particles of each particle size fraction larger than 1mm is smaller than the particle size ratio intermediate value; when the three-dimensional potted plant is a large-scale plant, the volume percentage of the crushed grains of each grain size which is larger than 1mm is larger than the median of the grain size ratio. In the process, according to the difference between the ratio of each particle size fraction of the measured mixture and the median value, when the volume percentage after adjustment exceeds 100% or is lower than 100%, the ratio of particles with the particle size of less than 1mm is reduced or increased to carry out filling balance, so that the standard ratio of the particle sizes is achieved, and the mixture is uniformly mixed.

It is worth mentioning that the organic components are preferably peat, coconut coir, harmless fermentation products obtained by fermentation of planting, breeding and garden waste, and the like, before measuring the volume ratio of each grain fraction of the organic components, the raw materials of the harmless fermentation products obtained by fermentation of the planting, breeding and garden waste in the organic components need to be cut into pieces with the grain size of less than 30mm, the fermentation temperature is controlled to be above 65 ℃, when the fermentation temperature is 480 hours, the fermentation humidity is 60-80% of wet base water, the pH of the base product is adjusted to 0-8.5, the conductivity EC is less than or equal to 0.5ms/cm, the organic matter is more than or equal to 30%, and the density is less than or equal to 0.8T/m 3.

Through years of research, the inventor of the invention finds that in order to meet the requirements, the proportion of inorganic components in the substrate can be controlled, meanwhile, the particle size distribution of the inorganic components can be respectively controlled, the standard pore size distribution can be achieved by reconstructing the standard particle size distribution of the greening substrate, the scientific and reasonable water-gas configuration of the cultivation substrate is established, and the water, oxygen and nutrient supply required by three-dimensional greening is met to the maximum extent. The inventor considers that according to theoretical analysis, in order to meet the growth requirements of different plant species, the proportion of different size fractions in the substrate needs to be controlled according to the size of the plant species, and the requirements of the different plant species on the greening substrate are guaranteed.

Specifically, the three-dimensional potted plant or container culture substrate is formed by mixing inorganic components and organic components with different particle sizes (the organic components are more than or equal to 30), the middle value of the proportion of each particle size fraction of the three-dimensional greening substrate is set, the proportion of each particle size fraction is adjusted according to the middle value by different plant types, the particle size smaller than 1mm is usually used as a main particle for adjusting the volume proportion, when the volume percentage of the adjusted substrate exceeds 100%, the particle size smaller than 1mm is reduced for completing balance, and when the volume percentage of the adjusted substrate is lower than 100%, the particle size smaller than 1mm is increased for completing balance.

And through theoretical research and experimental verification of the inventor, the matrix can reach the following standard, and the volume weight of the physical index of the matrix is less than or equal to 0.8T/m³The three-dimensional greening culture substrate comprises 15-30% of ventilation pores, 50-85% of total porosity, 40-50% of water holding pores, and the weight ratio of PH: 5.0-8.5, and the EC value of the conductivity is less than or equal to 0.5m³/cm。

When the volume percentage of the crushed particles with the size of more than 10mm in the matrix is too large, the proportion of the ventilation pores of the matrix is increased, and the water retention is poor.

The proper particle size of over 10mm is favorable to maintaining the absorption and storage of the matrix and protecting the root system.

When the substrate of the invention is manufactured, 1-5 per mill of nitrogen phosphorus potassium compound fertilizer is added when the proportion of each grain size reaches the requirement, and a proper amount of bactericide, a proper amount of soil conditioner and a proper amount of plant growth regulator are added, and the dosage and the type are adjusted according to different plant types and are uniformly mixed.

As mentioned above, when the three-dimensional potted plant is a small plant, such as petunia, calendula, coreopsis, ophiopogon root, wild cattle grass and the like, the volume percentage of the particles of each size fraction larger than 1mm is smaller than the median of the particle size ratio; when the three-dimensional pot culture is large-scale plants, such as winter jasmine, fructus forsythiae and peony in woody plants, the volume percentage of the particles of which the clove is larger than 1mm in each size fraction is larger than the median of the particle size ratio. In addition, as in the sub-shrub: lavender, herba hyperici setifolii, thyme, part of rhododendron and the like, and the grain size ratio can be about the middle value.

FIG. 3 is a composition diagram of the average distribution of the potted plant substrate particles according to an embodiment of the present invention. As shown in fig. 3, the ratio of the different particle diameters of the inorganic component and the organic component is controlled as follows: the volume percentage of the crushed grains with the size of more than 15mm is 0-25%, the volume percentage of the crushed grains with the size of 10mm-15mm is 5-20%, the volume percentage of the crushed grains with the size of 5mm-10mm is 10-20%, the volume percentage of the crushed grains with the size of 1mm-5mm is 15-25%, and the volume percentage of the crushed grains with the size of less than 1mm is 25-55%.

In a preferred embodiment, the matrix comprises an organic component and an inorganic component; the inorganic component is at least one of perlite, slag, vermiculite and fly ash;

the organic component is selected to be at least one of: peat, coconut husk and planting, breeding and garden waste.

In a preferred embodiment, the three-dimensional pot culture is a small plant, the volume percentage of the crushed grains of each grain size fraction larger than 1mm is smaller than the grain size ratio intermediate value, and the grain size ratio intermediate value is as follows:

the volume percentage of the nibs having a size of the fraction greater than 15mm is 12.5%;

the volume percentage of the particles with the size of 10mm-15mm size fraction is 12.5%;

the volume percentage of the particles with the size of 5mm-10mm size fraction is 15%;

the volume percentage of the particles with the size of 1mm-5mm is 20 percent;

the volume percentage of the crushed pieces having a size of 1mm or less was 40%.

Preferably, the three-dimensional potted plant is a macrophyte, the volume percentage of the crushed grains of each grain size fraction larger than 1mm is larger than the median value of the grain size ratio, and the median value of the grain size ratio is as follows:

the volume percentage of the nibs having a size of the fraction greater than 15mm is 12.5%;

the volume percentage of the particles with the size of 10mm-15mm size fraction is 12.5%;

the volume percentage of the particles with the size of 5mm-10mm size fraction is 15%;

the volume percentage of the particles with the size of 1mm-5mm is 20 percent;

the volume percentage of the crushed pieces having a size of 1mm or less was 40%.

The invention also discloses a manufacturing method of the three-dimensional potted plant substrate, which comprises the following steps: obtaining a three-dimensional potting matrix and mixing the following components:

the volume percentage of the particles with the size of more than 15mm is 0-25%;

the volume percentage of the particles with the size of 10mm-15mm is 5% -20%;

the volume percentage of the particles with the size of 5mm-10mm is 10% -20%;

the volume percentage of the particles with the size of 1mm-5mm is 15% -25%;

the volume percentage of the particles with the size below 1mm is 25-55%.

Preferably, after the proportion of each particle size reaches the requirement, 1-5 per mill of nitrogen-phosphorus-potassium compound fertilizer is added and mixed evenly.

Preferably, the obtaining of the three-dimensional potting medium comprises:

cutting harmless fermentation product raw materials formed by fermenting planting and breeding wastes in organic components into particles with the particle size of less than 30mm, controlling the fermentation temperature to be more than 65 ℃, fermenting for 240-480 hours, and fermenting with the humidity and the water content (wet basis) of 60-70%. The pH value of the substrate product is adjusted to 6.0-8.5, the conductivity EC is less than or equal to 0.5ms/cm, the organic matter is more than or equal to 30 percent, and the density is less than or equal to 0.8T/m 3.

Preferably, the proportioning step comprises: enabling the substrate raw material to pass through a screen with 15mm sieve pores, taking the particles which do not pass through the 15mm sieve pores, and obtaining the particles with the particle size of more than 15mm, wherein the particles are the 1 st particle size;

taking the crushed particles which pass through a 15mm sieve mesh, and passing through a 10mm sieve mesh to obtain the crushed particles which do not pass through the sieve mesh as a 2 nd particle grade;

taking the crushed particles which pass through a 10mm sieve mesh, and passing through a 5mm sieve mesh to obtain 3 rd particle grade of the crushed particles which do not pass through the sieve mesh;

taking the crushed particles which pass through a 5mm sieve mesh, and passing through a 1mm sieve mesh to obtain 4 th particle grade of the crushed particles which do not pass through the sieve mesh;

taking the crushed particles which pass through a sieve pore of 1mm to obtain crushed particles with the particle size of less than 1mm, wherein the crushed particles are of the 5 th particle size;

mixing inorganic component particles and organic component particles of the 1 st size fraction, the 2 nd size fraction, the 3 rd size fraction, the 4 th size fraction and the 5 th size fraction in a set ratio.

Further preferably, the three-dimensional potting medium comprises inorganic components and organic components,

the inorganic component is at least one of perlite, slag, vermiculite and fly ash;

the organic component is selected to be at least one of: grass peat, coconut husk and planting and breeding wastes.

Example 1

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the accompanying drawings in combination with specific embodiments.

Fig. 1 is a process flow chart of a method for manufacturing a three-dimensional potting medium of the present invention, fig. 2 is a process flow chart of a crumb screening process of the three-dimensional potting medium of the present invention, as shown in fig. 1 and fig. 2, the screening process comprises the following steps:

grading and sieving the matrix raw materials, wherein the sieving steps are as follows:

and S101, carrying out a grading sieving process on the inorganic component crushed grains and the organic component crushed grains, taking the crushed grains which do not pass through a sieve hole of 15mm, and obtaining the crushed grains with the grain size of more than 15mm, wherein the crushed grains are the 1 st grain size. By this step, the 1 st fraction of the inorganic component granules and the 1 st fraction of the organic component granules can be obtained.

Step S102, taking the particles which pass through a 15mm sieve mesh, passing through a 10mm sieve mesh to obtain particles which do not pass through the sieve mesh as the 2 nd particle fraction, and obtaining the 2 nd particle fraction of inorganic component particles and the 2 nd particle fraction of organic component particles.

Step S103, taking the particles which pass through a sieve hole of 10mm, passing through a sieve of 5mm, and obtaining the particles which do not pass through the sieve hole as the 3 rd particle fraction, and obtaining the 3 rd particle fraction of the inorganic component particles and the 3 rd particle fraction of the organic component particles.

And step S104, taking the particles which pass through a 5mm sieve mesh, passing through a 1mm sieve mesh to obtain particles which do not pass through the sieve mesh as a 4 th particle fraction, and obtaining a 4 th particle fraction of inorganic component particles and a 4 th particle fraction of organic component particles.

Step S105, taking the particles which pass through a sieve hole of 1mm to obtain particles with particle size smaller than 1mm, wherein the particles are of 5 th particle size, and the 3 rd particle size of the inorganic component particles and the 3 rd particle size of the organic component particles are obtained.

The inorganic component particles and the organic component particles obtained by screening include: the particle size of the 1 st particle is larger than 15mm, the size of the 2 nd particle is 10mm-15mm, the size of the 3 rd particle is 5mm-10mm, the size of the 4 th particle is 1mm-5mm, and the size of the 5 th particle is smaller than 1 mm.

Setting an intermediate value of the ratio of the granules of each grade of the three-dimensional greening substrate according to the ratio of the granules of each grade adjusted according to the sizes of different plant species, adjusting the ratio of the granules of each grade according to the intermediate value by different plant species, generally taking the granules with the diameter smaller than 1mm as main granules for adjusting the ratio of the granules of each grade, performing compensation balance by reducing the ratio of the granules with the diameter smaller than 1mm when the adjusted volume percentage of the substrate exceeds 100%, and performing compensation balance by increasing the ratio of the granules with the diameter smaller than 1mm when the adjusted volume percentage of the substrate is lower than 100%.

FIG. 4 is a flow chart of a process for making a three-dimensional potting substrate according to an embodiment of the present invention. As shown in fig. 4:

the inorganic component raw materials are crushed and then the proportion of each grade is determined, the organic component raw materials which are crushed and then the proportion of each grade is determined are selected and added according to different plant species, and when the proportion of each grade is insufficient or exceeds the proportion of the volume ratio, the granules with the grade less than 1mm are screened out to supplement or reduce the granules to reach the reasonable range of the grade distribution. This embodiment may be to mix the inorganic component and the organic component in a ratio, for example: when the current plant species and the environment need to use all the inorganic component particles, the inorganic component particles account for 100 percent, and the organic component particles account for 0 percent. When it is determined that the current plant species and the environment need to use both the inorganic component crushed grains and the organic component crushed grains, the object can be achieved by adjusting the ratio of the inorganic component crushed grains to the organic component crushed grains, for example, 70% of the inorganic component crushed grains and 30% of the organic component crushed grains. The specific inorganic component particles and organic component particles can be set independently according to different plants, requirements and environments.

Table 1 shows an actual experiment of the three-dimensional potting medium of this embodiment for planting of maidenhair, which is cultivated in an open pond of a simulated base from 6 months in 2017 to 10 months in 2017, wherein each group has 40 pots, the planting density is 1 plant/pot, and the total is 3 formula groups and 1 control group, wherein 3 formula groups correspond to the three-dimensional potting medium formulas of examples 1 to 3, respectively, and the control group is the three-dimensional potting medium formula of example 4.

TABLE 1 three-dimensional potted plant substrate for planting test of peacock flowers

Numbering	Fresh weight on the ground g	Fresh weight of underground g	Dry weight of ground g	Underground dry weight g
					1-1	141	3.46	35.71	1.96
2-1	145	2.48	41.02	1.46
					3-1	85	2.26	21.61	1.31
4-1	17	1.82	8.48	1.04

For example, the volume percentage of the 1 st-size fraction with the size of more than 15mm, the volume percentage of the 2 nd-size fraction with the size of 10mm-15mm, the volume percentage of the 3 rd-size fraction with the size of 5mm-10mm, the volume percentage of the 4 th-size fraction with the size of 1mm-5mm and the volume percentage of the 5 th-size fraction below 1mm are more than 40%.

When the grain size ratio reaches the requirement, 1-5 per mill of nitrogen-phosphorus-potassium compound fertilizer is added and uniformly mixed to serve as a three-dimensional pot culture substrate for planting the peacock flowers.

Setting an intermediate value of the ratio of the granules of each grade of the three-dimensional greening substrate according to the ratio of the granules of each grade adjusted according to the sizes of different plant species, adjusting the ratio of the granules of each grade according to the intermediate value by different plant species, generally taking the granules with the diameter smaller than 1mm as main granules for adjusting the ratio of the granules of each grade, performing compensation balance by reducing the ratio of the granules with the diameter smaller than 1mm when the adjusted volume percentage of the substrate exceeds 100%, and performing compensation balance by increasing the ratio of the granules with the diameter smaller than 1mm when the adjusted volume percentage of the substrate is lower than 100%.

According to the small-sized plant, the organic component and the inorganic component can be controlled such that the volume percentage of the 1 st size fraction with a size of more than 15mm is 0%, the volume percentage of the inorganic component crushed particles with a size of 10mm-15mm is 5% and the volume percentage of the organic component crushed particles is 5% as the volume percentage of the 2 nd size fraction is 12.5%, the volume percentage of the inorganic component crushed particles with a size of 5mm-10mm is 10% and the volume percentage of the organic component crushed particles is 5% as the volume percentage of the 3 rd size fraction is 15%, the volume percentage of the inorganic component crushed particles with a size of 1mm-5mm is 10% and the volume percentage of the organic component crushed particles is 10% as the volume percentage of the 4 th size fraction is 20%, the volume percentage of the inorganic component particles having a size of 1mm or less was 40% and the volume percentage of the organic component particles having a size of 20% was 60% as the volume percentage of the 5 th fraction.

The inorganic component particles are mixed as follows: mixing 0% of the 1 st size fraction, 5% of the 2 nd size fraction, 10% of the 3 rd size fraction, 10% of the 4 th size fraction and 40% of the 5 th size fraction to obtain the inorganic component mixed matrix in the formula 1;

the organic component particles are mixed as follows: the organic component mixed matrix in formula 1 was obtained by mixing 0% of the 1 st size fraction, 7.5% of the 2 nd size fraction, 5% of the 3 rd size fraction, 10% of the 4 th size fraction and 20% of the 5 th size fraction thoroughly, and adjusting the proportion of the upper or lower size fraction of 1mm according to the plant size when the total amount of the size fractions was less than 100%.

Further, mixing the inorganic component particles and the organic component particles to obtain the three-dimensional potting matrix of the formula 1, adding 4 per mill of nitrogen-phosphorus-potassium compound fertilizer when the grain size ratio meets the requirement, adding a proper amount of bactericide, a proper amount of soil conditioner and a proper amount of plant growth regulator, adjusting the dosage and the type according to market commodity requirements, and uniformly mixing to obtain the final three-dimensional greening matrix. The test data of the actual planting is shown in the test data corresponding to the formula 1 in the table 1.

Example 2

The manufacturing method is the same as example 1, except that the ratio of the particle diameters of the inorganic component crushed particles and the organic component crushed particles is adjusted to:

0% by volume of the 1 st fraction having a size of more than 15mm, 5% by volume of inorganic component particles having a size of 10mm to 15mm and 7.5% by volume of organic component particles as the 2 nd fraction, 12.5% by volume of inorganic component particles having a size of 5mm to 10mm and 10% by volume of organic component particles as the 3 rd fraction, 20% by volume of inorganic component particles having a size of 1mm to 5mm and 10% by volume of organic component particles as the 4 th fraction, the volume percentage of the inorganic component particles having a size of 1mm or less was 20% and the volume percentage of the organic component particles was 20% as the volume percentage of the 5 th fraction was 40%.

The inorganic component particles are mixed as follows: mixing 0% of the 1 st size fraction, 5% of the 2 nd size fraction, 10% of the 3 rd size fraction, 10% of the 4 th size fraction and 20% of the 5 th size fraction to obtain the inorganic component mixed matrix in the formula 1;

the organic component particles are mixed as follows: the organic component mixed matrix in formulation 1 was obtained by mixing 0% of size 1, 7.5% of size 2, 10% of size 3, 10% of size 4 and 20% of size 5.

Further, the inorganic component crushed grains and the organic component crushed grains are mixed to obtain the three-dimensional potting matrix of the formula 2, when the grain size ratio meets the requirement, 3 per mill of nitrogen-phosphorus-potassium compound fertilizer, a proper amount of bactericide, a proper amount of soil conditioner and a proper amount of plant growth regulator are added, the amount and the types of the plant growth regulator are adjusted according to market commodity requirements, and the mixture is uniformly mixed to serve as the final three-dimensional greening matrix. The test data of the actual planting is shown in the corresponding test data of the formula 2 in the table 1.

Example 3

The manufacturing method is the same as example 1, except that the ratio of the particle diameters of the inorganic component crushed particles and the organic component crushed particles is adjusted to:

the volume percentage of the 1 st fraction with the size of more than 15mm is 0 percent, the volume percentage of the inorganic component particles with the size of 10mm-15mm fraction is 5 percent, the volume percentage of the organic component particles with the size of 10mm-15mm fraction is 7.5 percent, the volume percentage of the inorganic component particles with the size of 5mm-10mm fraction is 5 percent, the volume percentage of the organic component particles with the size of 10 percent is 15 percent, the volume percentage of the inorganic component particles with the size of 1mm-5mm fraction is 10 percent, the volume percentage of the organic component particles with the size of 1mm-5mm fraction is 20 percent, the volume percentage of the inorganic component particles having a size of 1mm or less was 20% and the volume percentage of the organic component particles was 40%, as the volume percentage of the 5 th fraction was 60%.

The inorganic component particles are mixed as follows: mixing 0% of the 1 st size fraction, 5% of the 2 nd size fraction, 5% of the 3 rd size fraction, 5% of the 4 th size fraction and 15% of the 5 th size fraction to obtain the inorganic component mixed matrix in the formula 1;

the organic component particles are mixed as follows: the organic component mixed matrix in formulation 1 was obtained by mixing 0% of the 1 st size fraction, 10% of the 2 nd size fraction, 10% of the 3 rd size fraction, 10% of the 4 th size fraction and 40% of the 5 th size fraction.

Further, mixing the inorganic component particles and the organic component particles to obtain a three-dimensional potting matrix of a formula 3, adding 2 per mill of nitrogen-phosphorus-potassium compound fertilizer when the grain size ratio meets the requirement, adding a proper amount of bactericide, a proper amount of soil conditioner and a proper amount of plant growth regulator, adjusting the dosage and the type according to market commodity requirements, and uniformly mixing to obtain the final three-dimensional greening matrix. The test data of the actual planting is shown in the test data corresponding to the formula 3 in the table 1.

Example 4

The manufacturing method is the same as example 1, except that the matrix does not contain organic component particles, and the particle size of the inorganic component particles is adjusted to:

the volume percentage of the inorganic component crushed grains with the size of more than 15mm is controlled to be 0 percent, and the volume percentage of the crushed grains with the size of less than 1mm is controlled to be 40 percent.

The volume percentage of the inorganic component crushed particles with the size of 10mm-15mm is controlled to be 20%, the volume percentage of the crushed particles with the size of 5mm-10mm is controlled to be 20%, and the volume percentage of the crushed particles with the size of 1mm-5mm is controlled to be 20%.

The inorganic component particles are mixed as follows: the inorganic component mixed matrix in formulation 3 was obtained by mixing 0% of the 1 st size fraction, 20% of the 2 nd size fraction, 20% of the 3 rd size fraction, 20% of the 4 th size fraction, and 40% of the 5 th size fraction.

Furthermore, the three-dimensional potting medium of the formula 4 does not contain organic components of coconut coir and harmless fermentation products prepared by fermenting planting and breeding wastes. The test data of the actual planting is shown in the test data corresponding to the formula 4 in the table 1.

Example 5

Table 2 shows the practical experiment of the three-dimensional potting medium of this embodiment for planting cockscomb, which is to cultivate in open-air ponds of the three-dimensional greening simulation base from 6 months in 2017 to 11 months in 2017, wherein each group has 40 pots, the planting density is 1 plant/pot, 1 formula group and 1 control group, which correspond to the three-dimensional potting medium formula of the experimental data of example 5, number 1-1, and the control group corresponds to the three-dimensional potting medium formula of the experimental data of example 5, number 2-1.

TABLE 2 stereo potted plant substrate for cockscomb planting test

Numbering	Fresh weight on the ground g	Fresh weight of underground g	Dry weight of ground g	Underground dry weight g
					1-1	80	8.3	20.55	2.01
2-1	65	4.06	16.88	1.18

According to the cockscomb, which is a miniature plant, the organic and inorganic components can be controlled so that the particle size ratio is less than the median value, and the volume percentage of the 1 st size fraction having a size of more than 15mm is 0%, the volume percentage of the 2 nd size fraction having a size of 10mm to 15mm is less than 2012.5%, the volume percentage of the 3 rd size fraction having a size of 5mm to 10mm is less than 2015%, the volume percentage of the 4 th size fraction having a size of 1mm to 5mm is less than 20%, and the volume percentage of the 5 th size fraction having a size of 1mm or less is more than 40%.

When the grain size ratio reaches the requirement, 1-5 per mill of nitrogen-phosphorus-potassium compound fertilizer is added and uniformly mixed to be used as a three-dimensional potted plant substrate for planting the cockscomb.

Setting an intermediate value of the ratio of the granules of each grade of the three-dimensional greening substrate according to the ratio of the granules of each grade adjusted according to the sizes of different plant species, adjusting the ratio of the granules of each grade according to the intermediate value by different plant species, generally taking the granules with the diameter smaller than 1mm as main granules for adjusting the ratio of the granules of each grade, performing compensation balance by reducing the ratio of the granules with the diameter smaller than 1mm when the adjusted volume percentage of the substrate exceeds 100%, and performing compensation balance by increasing the ratio of the granules with the diameter smaller than 1mm when the adjusted volume percentage of the substrate is lower than 100%.

According to the cockscomb as a small plant, the organic and inorganic components can be controlled such that the volume percentage of the 1 st size fraction with a size of more than 15mm is 0%, the volume percentage of the inorganic component crushed particles with a size of 10mm-15mm is 105% and the volume percentage of the organic component crushed particles is 5% as the volume percentage of the 2 nd size fraction is 1512.5%, the volume percentage of the inorganic component crushed particles with a size of 5mm-10mm is 10% and the volume percentage of the organic component crushed particles is 5% as the volume percentage of the 3 rd size fraction is 15%, the volume percentage of the inorganic component crushed particles with a size of 1mm-5mm is 10% and the volume percentage of the organic component crushed particles is 510% as the volume percentage of the 4 th size fraction is 1520%, the volume percentage of the inorganic component particles having a size of 1mm or less was 40% and the volume percentage of the organic component particles was 1520%, as the volume percentage of the 5 th fraction, was 5560%.

The inorganic component particles are mixed as follows: mixing 0% of the 1 st size fraction, 105% of the 2 nd size fraction, 10% of the 3 rd size fraction, 10% of the 4 th size fraction and 40% of the 5 th size fraction to obtain an inorganic component mixed matrix in the formula 1;

the organic component particles are mixed as follows: the organic component mixed matrix in formulation 1 was obtained by mixing 0% of size 1, 7.5% of size 2, 5% of size 3, 10% of size 4 and 20% of size 5.

Further, mixing the inorganic component particles and the organic component particles to obtain the three-dimensional potted plant substrate of the formula 1, adding 5 per mill of nitrogen-phosphorus-potassium compound fertilizer and adding a proper amount of bactericide when the proportion of each particle fraction meets the requirement,proper amount of soil regulator and proper amount and kind of plant growth regulator are added according to the requirement of market commodityTo masterAdjusting and mixing uniformly to obtain the final three-dimensional greening matrix. The test data of the actual planting is shown in the test data corresponding to the formula 1 in the table 2.

From the planting tests of the malachite grass and the cockscomb, the formula of the potted three-dimensional greening substrate is close to 60% of the size fraction smaller than 1mm, the sum of the four size fractions larger than 1mm is close to 40% of the size fraction, the volume ratio of the size fraction smaller than 1mm and smaller than 40% of the control group is obvious, and the experiments show that 3 formulas of the malachite grass and 1 formula of the cockscomb are better than the control group, so the experiments prove that the substrate for small herbaceous flower plants is close to thinner, the water retention is better, and the permeability can be properly lower.

The proper permeability and water retention property are beneficial to accumulation of dry and fresh substances on the overground part and the underground part, the small-sized plants have poor water retention property and poor water retention type, the growth vigor can be reduced, the roots of the tall and large-sized plants are developed and deep, the proper permeability is improved, the growth of crops is not influenced, and the water retention load can be reduced.

The above-mentioned embodiments are intended to illustrate the objects, technical solutions and advantages of the present invention in further detail, and it should be understood that the above-mentioned embodiments are only exemplary embodiments of the present invention and are not intended to limit the present invention, and any modifications, equivalents, improvements and the like made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (9)

1. A three-dimensional potted plant substrate is characterized in that,

the volume percentage of the particles with the size of more than 15mm is 0-25%;

the volume percentage of the particles with the size of 10mm-15mm is 5% -20%;

the volume percentage of the particles with the size of 5mm-10mm is 10% -20%;

the volume percentage of the particles with the size of 1mm-5mm is 15% -25%;

the volume percentage of the particles with the size below 1mm is 25-55%.

2. The three-dimensional potting substrate of claim 1, wherein: comprises an organic component and an inorganic component;

the inorganic component is selected from at least one of perlite, slag, vermiculite or fly ash;

the organic component is selected to be at least one of: peat, coconut husk and planting, breeding and garden waste.

3. The three-dimensional potting substrate of claim 1, wherein: the three-dimensional potted plant is a small plant, the volume percentage of broken grains of each grain size which is larger than 1mm is smaller than the median of the grain size ratio, and the median of the grain size ratio is as follows:

the volume percentage of the nibs having a size of the fraction greater than 15mm is 12.5%;

the volume percentage of the particles with the size of 10mm-15mm size fraction is 12.5%;

the volume percentage of the particles with the size of 5mm-10mm size fraction is 15%;

the volume percentage of the particles with the size of 1mm-5mm is 20 percent;

the volume percentage of the crushed pieces having a size of 1mm or less was 40%.

4. The three-dimensional potting substrate of claim 1, wherein: the three-dimensional potted plant is a large-scale plant, the volume percentage of broken grains of each grain size larger than 1mm is larger than the median of the grain size ratio, and the median of the grain size ratio is as follows:

the volume percentage of the nibs having a size of the fraction greater than 15mm is 12.5%;

the volume percentage of the particles with the size of 10mm-15mm size fraction is 12.5%;

the volume percentage of the particles with the size of 5mm-10mm size fraction is 15%;

the volume percentage of the particles with the size of 1mm-5mm is 20 percent;

the volume percentage of the crushed pieces having a size of 1mm or less was 40%.

5. The manufacturing method of the three-dimensional potting medium is characterized in that the three-dimensional potting medium is obtained and is prepared according to the following mixture ratio:

the volume percentage of the particles with the size of more than 15mm is 0-25%;

the volume percentage of the particles with the size of 10mm-15mm is 5% -20%;

the volume percentage of the particles with the size of 5mm-10mm is 10% -20%;

the volume percentage of the particles with the size of 1mm-5mm is 15% -25%;

the volume percentage of the particles with the size below 1mm is 25-55%.

6. The manufacturing method according to claim 5, further comprising:

when the proportion of each particle fraction meets the requirement, 1-5 per mill of nitrogen-phosphorus-potassium compound fertilizer is added and mixed evenly.

7. The manufacturing method according to claim 5, characterized in that: the method for obtaining the three-dimensional potting matrix comprises the following steps:

cutting harmless fermentation product raw materials formed by fermenting planting and breeding wastes in organic components into particles with the particle size of less than 30mm, controlling the fermentation temperature to be more than 65 ℃, fermenting for 240-480 hours, adjusting the fermentation humidity to 60-70% of wet base water, adjusting the pH value of a substrate product to be 0-8.5, adjusting the electric conductivity EC to be less than or equal to 0.5ms/cm, adjusting the organic matter to be more than or equal to 30%, and adjusting the density to be less than 0.8T/m 3.

8. The manufacturing method according to claim 5, characterized in that: the proportioning step comprises the following steps: enabling the substrate raw material to pass through a screen with 15mm sieve pores, taking the particles which do not pass through the 15mm sieve pores, and obtaining the particles with the particle size of more than 15mm, wherein the particles are the 1 st particle size;

taking the crushed particles which pass through a 15mm sieve mesh, and passing through a 10mm sieve mesh to obtain the crushed particles which do not pass through the sieve mesh as a 2 nd particle grade;

taking the crushed particles which pass through a 10mm sieve mesh, and passing through a 5mm sieve mesh to obtain 3 rd particle grade of the crushed particles which do not pass through the sieve mesh;

taking the crushed particles which pass through a 5mm sieve mesh, and passing through a 1mm sieve mesh to obtain 4 th particle size fraction of the crushed particles which do not pass through the sieve mesh;

taking the crushed particles which pass through a sieve pore of 1mm to obtain crushed particles with the particle size of less than 1mm, wherein the crushed particles are of the 5 th particle size;

mixing inorganic component particles and organic component particles of the 1 st size fraction, the 2 nd size fraction, the 3 rd size fraction, the 4 th size fraction and the 5 th size fraction in a set ratio.

9. The manufacturing method according to claim 5, characterized in that: the three-dimensional pot culture substrate comprises an inorganic component and an organic component,

the inorganic component is selected from at least one of perlite, slag and vermiculite;

the organic component is selected to be at least one of: grass peat, coconut husk and planting and breeding waste are fermented to form harmless fermentation products.

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