NL2031846B1 - Method for recovering nutrients from vegetable streams - Google Patents

Abstract

The present invention relates to a method for recovering nutrients from vegetable streams. Furthermore, the present invention relates to the special use of the nutrients obtained thereby. An aim of the present invention is to use such nutrients as high-quality fertilizers, in particular for the organic cultivation of crops.

Description

Title: Method for recovering nutrients from vegetable streams

The present invention relates to a method for recovering nutrients from vegetable streams. Furthermore, the present invention relates to the special use of the nutrients obtained thereby.

A method for preparing fertilizer from plant sap is known from

Dutch patent NL 1043459. The method known from it includes the following steps: squeezing plants, resulting in plant juice, the mineralization of the obtained plant juice in an aerobic bioreactor and extracting the nitrogen to a separate reactor, filtering remaining organic matter , resulting in clean liquid with minerals without nitrogen and splitting of the resulting minerals after which concentration of the single elements is carried out.

A 1970 scientific publication by Heisler E.G. et al. entitled “Potato starch factory waste effluents |. Recovery of potassium and other inorganic cations”, 1970, American Potato Journal, vol. 47, pp. 326-336 discloses a method for recovering valuable constituents from potato starch factory waste water, involving five steps: (i) concentrating to about 4-5% solids by reverse osmosis, (ij) allowing precipitation of protein by steam injection; (iii) separation and recovery of a fertilizer mixture of potassium and other inorganic cations by ion exchange: (iv) separation and recovery of amino compounds by ion exchange; and {v) recovery of organic acids (mainly citric acid) and phosphates by ion exchange.

The American patent US 6,274,105 relates to a method for producing potassium salts of high purity using agricultural or fermentation by-products, which involves the following steps: feeding an already liquid agricultural or fermentation by-product containing potassium and organic compounds, to a cation exchange resin, then stripping the resin to form a potassium-containing solution, neutralizing and concentrating the potassium-containing solution, and finally crystallizing the potassium salt therefrom.

From the Chinese publication CN 102319592 it is known to recover cations, in particular K and Ca, via ion exchange.

Nutrients can be divided into two groups, namely micronutrients and macronutrients. Examples of micronutrients are molybdenum, nickel, copper, zinc and iron. Examples of macronutrients include phosphorus, magnesium, calcium, potassium, nitrogen, oxygen and carbon. All plants need minerals to grow. These are essential nutrients that the plant absorbs from the soil along its roots along with water. A lack of minerals in the soil quickly results in restriction of plant growth. They play an essential role in important enzymatic reactions such as photosynthesis and nitrogen fixation. If one of these elements is deficient, the plant's growth will be hampered, even if all other elements are present in sufficient quantities. Not only the absolute quantities but also the mutual proportions must be in balance. In case of deficiencies or unbalanced nutrition, symptoms such as leaf discoloration may occur. For a qualitatively and quantitatively good crop yield, it is important that there are sufficient nutrients for the crops, in addition to favorable growth conditions in the soil such as structure, acidity and nutrient supply.

For the organic cultivation of crops, it is desirable that nutrients of organic origin are used. After all, an organic grower grows without chemical synthetic pesticides and certainly does not use artificial fertilizer.

Organic is a protected concept and a product may only be sold as organic if it meets EU legal requirements. In the Netherlands, Skal is the independent organization that ensures that organic growers adhere to these regulations. The growers then receive a Skal certificate. Only with this certificate may the EU-BIO logo and the Skal number: NL-BIO-01 be used.

Remains of plants and crops, but also roadside cuttings, agricultural and forestry materials, heath grass and clippings contain many useful minerals that can be processed into high-quality fertilizers.

An aim of the invention is the recovery of nutrients from vegetable streams.

Another aim of the invention is to use such nutrients as high-quality fertilizers, in particular for the organic cultivation of crops.

The invention as mentioned in the introduction thus relates to a method for recovering nutrients from vegetable streams, which method comprises: i) providing one or more starting materials of vegetable origin,

ii) exerting pressure on one or more starting materials according to i) to obtain one or more juice flows, ii) recovering nutrients from the aforementioned one or more juice flows and starting materials of vegetable origin.

The present inventors have found that with such a method the nutrients still present in the starting materials of vegetable origin can be recovered and can subsequently be used as components of high-quality fertilizers, for example for the organic cultivation of crops.

In an example, the aforementioned one or more starting materials of vegetable origin have been selected from the group of remains of plants and crops, liquid residual flows from the food industry obtained during the processing or processing of beer, corn, sugar, and potatoes.

In an example, step iii) comprises one or more separation steps selected from the group of hydrolysis, flocculation, filtration, electrodialysis and ion exchange, or a combination thereof.

In an example, step iii) comprises a hydrolysis step, after which the hydrolyzed stream is subjected to a step to obtain a protein-rich stream and a protein-depleted stream. The hydrolysis step is, for example, selected from the group of enzymatic hydrolysis, thermal hydrolysis and acid hydrolysis, or a combination thereof.

In one example, the step to obtain a protein-rich stream is selected from flocculation, filtration and electrodialysis, or a combination of these.

In an example, the resulting protein-rich stream is subjected to a homogenization step to obtain a stream with a high protein content.

In one example, the deproteinized stream is subjected to a calcium and magnesium recovery step to obtain a calcium and magnesium rich stream and a calcium and magnesium poor stream.

In one example, the step for recovering calcium and magnesium is selected from the group of filtration, ion exchange and electrodialysis, or a combination of these.

In an example, the stream low in calcium and magnesium is further subjected to one or more separation steps to obtain a potassium-rich stream, a phosphate-rich stream and a sulfate-rich stream.

In an example, the aforementioned separation steps are chosen from filtration, ion exchange, electrodialysis and magnetism, or a combination of these.

In an example, the stream poor in calcium and magnesium is first subjected to one or more separation steps to obtain a stream rich in potassium, after which the residual stream obtained is subjected to one or more separation steps to obtain a stream rich in phosphates and the subsequent the residual stream obtained thereby is subjected to one or more separation steps to obtain a stream rich in sulphates.

The present invention also concerns the use of one or more product flows obtained according to the method described above for the organic cultivation of crops, in particular organic cultivation on a substrate.

The present invention will be explained below using an example. The example includes a figure showing a flowchart of the individual process steps.

Vegetable residual flows 1, for example remains of plants and crops, but also roadside cuttings, agricultural and forestry material, heath grass and grass clippings, are used as starting material and subjected to a pressing step 2. Liquid residual flows 3, for example from the food industry obtained during the processing or processing of beer, corn, sugar, and potatoes, are not subjected to a pressing step. Fibers 33 can also be separated from the vegetable residual flows 1 and processed into cellulose 34. The resulting flows are subjected to enzymatic hydrolysis 4 and/or mechanical hydrolysis 5. The resulting flows are then subjected to a flocculation step 6, filtration step 7 and/ or electrodialysis 8 of protein takes place. The stream obtained is subjected to a step for recovering calcium and magnesium, in particular via ion exchange 9 and/or filtration 10. The stream also obtained is subjected to a step 25 for homogenizing proteins, after which a concentration step 29 is being executed. In step 28, calcium and magnesium are separated using electrodialysis and then a concentration step 32 takes place. In particular, calcium is recovered by ion exchange 26 to obtain a concentrated calcium-containing stream

30. In particular, magnesium is recovered by ion exchange 27 to obtain a concentrated magnesium-containing stream 31.

The stream obtained from flocculation step 6, filtration step 7 and/or electrodialysis 8 is stripped of potassium, in particular via filtration 11, ion exchange 12, 5 electrodialysis 13, whereby a concentrated potassium-containing stream 14 is obtained. The stream obtained from flocculation step 8, filtration step 7 and/or electrodialysis 8 is removed from phosphates, in particular via electrodialysis 15, magnetization 18, filtration 17 and/or ion exchange 18, whereby a concentrated stream 19 containing phosphates is obtained. The stream obtained from flocculation step 8, filtration step 7 and/or electrodialysis 8 is removed from sulphates, in particular via filtration 20, electrodialysis 21, bipolar electrodialysis 22 and/or ion exchange 23, whereby a concentrated stream 24 containing sulphates is obtained.

Claims (13)

CONCLUSIONS 1. Method for recovering nutrients from vegetable streams, which method comprises: i) providing one or more starting materials of plant origin, ii) exerting pressure on one or more starting materials according to i) to obtain one or more juice flows, iii) recovering nutrients from the aforementioned one or more juice flows and starting materials of vegetable origin. 2. Method according to claim 1, characterized in that said one or more starting materials of vegetable origin are selected from the group of remains of plants and crops, liquid residual flows from the food industry obtained during the processing or processing of beer, corn, sugar , and potato. 3. Method according to one or more of the preceding claims, characterized in that step iii) comprises one or more separation steps, selected from the group of hydrolysis, flocculation, filtration, electrodialysis and ion exchange, or a combination thereof. Method according to claim 3, characterized in that step iii) comprises a hydrolysis step, after which the stream subjected to hydrolysis is subjected to a step to obtain a protein-rich stream and a protein-depleted stream. Method according to claim 4, characterized in that the step to obtain a protein-rich stream is selected from flocculation, filtration and electrodialysis, or a combination thereof. 6. Method according to claim 5, characterized in that the resulting protein-rich stream is subjected to a homogenization step to obtain a stream with a high protein content. 7. Method according to one or more of claims 4-6, characterized in that the stream that has been deproteinized is subjected to a step for recovering calcium and magnesium therefrom, wherein a stream is rich in calcium and magnesium and a stream is poor in calcium and magnesium. magnesium are obtained. Method according to claim 7, characterized in that the step for recovering calcium and magnesium is selected from the group of filtration, ion exchange and electrodialysis, or a combination thereof. A method according to claim 7, characterized in that the stream low in calcium and magnesium is further subjected to one or more separation steps to obtain a stream rich in potassium, a stream rich in phosphates and a stream rich in sulphates. Method according to claim 9, characterized in that said separation steps are selected from filtration, ion exchange, electrodialysis and magnetism, or a combination thereof. 11. Method according to one or more of claims 9-10, characterized in that the stream poor in calcium and magnesium is first subjected to one or more separation steps to obtain a stream rich in potassium, after which the residual stream obtained is subjected to one or more separation steps to obtain a stream rich in phosphates and the residual stream subsequently obtained is subjected to one or more separation steps to obtain a stream rich in sulphates. Method according to claim 3, characterized in that said hydrolysis step is selected from the group of enzymatic hydrolysis, thermal hydrolysis and acid hydrolysis, or a combination thereof. 13. Use of one or more product flows obtained according to one or more of the preceding claims for the organic cultivation of crops, in particular organic cultivation on a substrate.