KR20170001688U - An apparatus for separating nutrient from hydroponic waste solution - Google Patents

Abstract

A waste nutrient separation device is disclosed. A waste nutrient separation apparatus for a waste nutrient solution comprises: a waste nutrient solution storage tank for storing a waste nutrient solution discharged from a cultivation tank; a filtration unit for separating the nutrient solution component and moisture except the nutrient solution component from the waste nutrient solution; A circulation pump for supplying the filtrate from the tank to the filtration unit; a nutrient solution concentration tank for storing the nutrient solution component separated from the filtration unit; and a treatment water storage tank for storing the water separated from the filtration unit, Re-filter the nutrient solution components stored in the nutrient solution concentration tank n times (n is a natural number greater than 1).

Description

FIELD OF THE INVENTION [0001] The present invention relates to a waste liquid nutrient separation apparatus,

The present invention relates to an apparatus for collecting waste nutrient solution discharged from a hydroponic culture system to separate the nutrients contained in the waste nutrient solution and the moisture of the treated waste nutrient solution.

As vegetable consumption increases, hydroponic cultivation area is increasing year by year, but environmental pollution problem caused by increasing amount of pulp nutrient is serious every year. Recycling rate of pulp nutrient solution discharged from domestic hydroponics is about 5%, which is insufficient compared with 70% of Dutch developed countries and 45% of Japan. Therefore, it is urgently required to recycle waste nutrients to prevent environmental pollution. Methods for the use of pulmonary nutrients are largely in three forms: recycling of culture fluid, minimization of drainage, and reprocessing of drainage.

It is distinguished from the circulation type in which the drainage is recycled in hydroponics and the non-circulation type in which the drainage is released as it is. Particularly, in Korea, noncirculating solid medium using cocofeed, rocky surface, etc. accounts for more than 80%, and most vegetables are. In hydroponic cultivation, nutrient solution is supplied more than the required amount of plant, resulting in 20 ~ 30% drainage. Drainage is high in salt concentration, which leads to wasted fertilizer and water resources and environmental pollution.

  In the United States, it is reported that the cost of installing the Ebb & Flow system, which is a type of circulation method, is about 60% of the greenhouse construction cost. Domestic facility cultivation is operated on a small scale, so it is difficult to invest the facility cost to introduce the circulation type. In addition, there is a lack of awareness of the problem of environmental pollution, and most of them are non-circulating. Since the waste liquid is discharged to the soil or the river as it is, it causes waste of fertilizer as well as groundwater and environmental pollution. . However, the individual ions of the nutrient solution are absorbed in accordance with the growing stage of the crop, making it difficult to use them without adjusting the ion concentration of the discharged drain. There is a study on the method of analyzing and adjusting the individual ions of the drainage to control the nutrient solution of the circulating hydroponic cultivation and the method of adjusting the electric conductivity based on the method. The analysis of the nutrient management of hydroponic cultivators for the use of waste nutrients and the cultivation of the nutrients have been carried out.

 Recycling of the culture liquid is performed by circulating the culture liquid through the filtration, sterilization, and analysis of nutrients in the culture liquid to generate a nutrient balance of the culture liquid and reusing it for hydroponic cultivation. However, additional facilities and analytical techniques are required to balance the sterilization and nutrients, making it difficult to use in small-scale domestic farms.

  A system for minimizing the amount of culture fluid, which is also referred to as a drainage system, is a non-recycling method in which a sensor is installed at the outlet of a culture medium to minimize the amount of culture fluid discharged by shutting off the supply at the point of discharge. . However, additional equipment, such as sensors, and new nutrient management technologies are needed because the nutrient supply, recovery, and concentration vary with medium, crop, growing season, and environmental conditions.

  In addition, the reprocessing of the culture liquid requires a technique and equipment for separating the nutrients by filtration, sterilization and concentration after the hydroponic cultivation, reusing the water as raw water, and concentrating the liquid to the other crops . Currently, drainage from domestic plantation sites is sometimes used as a supplement to some house or nosy cultivation. However, limitations and drainage of distances between the area where drainage occurs and the area where it is used occur every day. However, There is a problem.

Thus, recycling of pulp nutrient solution from hydroponic cultivation is not generalized in farmers due to problems of facilities and equipment, analysis technology, seasonal and geographical limitation of generation and use of waste nutrient solution. It is urgent to establish efficient recycling technology of waste liquid to reduce raw water and fertilizer and prevent environmental pollution in the cultivation of facilities.

In order to solve such problems, the present invention aims to provide a waste nutrient separation device for treating and reusing hydroponically cultured waste nutrients at low cost and high efficiency.

In order to solve the above problems, an apparatus for separating a waste nutrient solution according to an embodiment of the present invention comprises: a waste nutrient solution storage tank for storing a waste nutrient solution discharged from a cultivation tank; A circulation pump for supplying the waste nutrient solution from the waste nutrient solution storage tank to the filtration unit, a nutrient solution concentration tank for storing the nutrient solution component separated from the filtration unit, and a storage tank for storing the water separated from the filtration unit And the filtration unit re-filtrates the nutrient solution components stored in the nutrient solution concentration tank n times (n is a natural number greater than 1).

The filtering unit may be a reverse osmosis filter, and the n may be set to 6.

The waste liquid nutrient separation apparatus according to one embodiment of the present invention may further include a sterilizing unit for sterilizing the waste nutrient solution collected from the cultivation tank and supplying the waste nutrient solution to the waste nutrient solution storage tank, have.

The waste liquid nutrient separation apparatus according to one embodiment of the present invention includes a first valve disposed between the waste nutrient solution storage tank and the circulation pump, a second valve disposed between the nutrient solution concentration tank and the circulation pump, And a valve control unit for controlling opening and closing of the first valve and the second valve.

Wherein the valve control unit controls the first valve to be in the open state and the second valve to be in the closed state when the waste nutrient solution liquid remains in the waste nutrient solution storage tank, The first valve may be closed and the second valve may be open.

According to the apparatus according to the present invention, it is possible to separate high quality and high quality nutrients from pulp nutrient solution, and it is economically effective because it can be used as fertilizer for cultivation of house, cultivation of house, or as nutrient solution for hydroponic cultivation. In addition, unlike the conventional waste liquid treatment method, since the volume of the nutrient solution component can be reduced by increasing the concentration, the cost, time and labor required for transportation can be reduced.

FIG. 1 is a block diagram showing the construction of a waste liquid nutrient separation apparatus according to an embodiment of the present invention.
2 is a graph showing the electrical conductivity and the hydrogen ion concentration in the concentrated nutrient solution according to the degree of concentration of the waste nutrient solution.
3 is a graph showing the electric conductivity and the hydrogen ion concentration of the treated water according to the degree of concentration of the waste nutrient solution.
4 is a graph showing the number of treatments of the waste nutrient solution and the treatment volume per unit time.
5 is a graph showing changes in the number of treatments of the waste nutrient solution, the electrical conductivity and the pH of the concentrated nutrient solution.

The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It should be understood, however, that the appended claims are not intended to limit the invention to the particular forms disclosed, but to include all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

The terms first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

The terms used in this specification are used only to describe certain embodiments and are not intended to limit the present invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present specification, the terms "comprises" or "having" are used to specify that a feature, a number, a step, an operation, an element, a part or a combination thereof is present, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the relevant art and are to be interpreted as ideal or overly formal in meaning unless explicitly defined in the present invention Do not.

Will be described in more detail with reference to the drawings according to the present invention.

FIG. 1 is a block diagram showing the construction of a waste liquid nutrient separation apparatus according to an embodiment of the present invention.

The waste nutrient solution separating apparatus according to an embodiment of the present invention includes a waste nutrient solution storage tank 200, a circulation pump 300, a filtration unit 600, a treated water storage tank 500, and a nutrient solution concentration tank 400 .

The waste nutrient solution storage tank 200 stores the waste nutrient solution discharged from the cultivation tank 100. 1, the waste nutrient solution storage tank 200 is directly connected to the cultivation tank 100 through a pipe. However, the waste nutrient solution storage tank 200 need not necessarily be directly connected to the cultivation tank 100, The waste nutrient solution collected from the tank 100 by another method may be transported to the waste nutrient solution storage tank 200 for storage.

The circulation pump 300 draws the waste nutrient solution stored in the waste nutrient solution storage tank 200 into the filtration unit 600. As the circulation pump 300, a multi-aperture pump or the like may be used, and the operating pressure of the circulation pump 300 may be adjustable.

The filtration unit 600 separates the pulp nutrient solution introduced by the circulation pump 300 into a nutrient solution containing nutrients and water containing no nutrients. The filtration unit 600 includes a separation filtration membrane that separates the nutrient solution component and the moisture. The separation filtration membrane may be a nanofiltration membrane, a reverse osmosis membrane, or the like.

 The process water storage tank 500 stores separated moisture (not including nutrients) in the filtration unit 600. The stored water can be reused as raw water for hydroponic cultivation, and the conductivity and hydrogen ion concentration (pH) can be treated to almost the same level as the original raw water so that the soil can be discharged.

The nutrient solution concentration tank 400 stores nutrient components separated by the filtration unit 600. The separated nutrient solution is in a state of high concentration due to removal of water.

According to the present invention, it is possible to increase the degree of concentration of the nutrient solution components by re-filtering the nutrient solution components stored in the nutrient solution concentration tank 400 several times.

For such an inventory of the concentration, the nutrient solution component stored in the nutrient solution concentration tank 400 is re-introduced into the filtration unit 600 through the circulation pump 300 and re-separated into the nutrient solution component and the water in the manner as described above . The re-separated water is sent to the treated water storage tank 500 and the nutrient solution components are sent to the nutrient concentration tank 400, respectively, and then the reprocessing is repeated in the same manner.

It is possible to filter the waste nutrient solution stored in the waste nutrient solution storage tank 200 and the concentrated nutrient solution stored in the nutrient solution concentration tank 400 at the same time but it is difficult to control the concentration because the nutrient solution concentrations of the incoming waste nutrient solution and the concentrated nutrient solution are different. Therefore, in order to control the concentration of the concentrated nutrient solution, it is preferable to first treat the waste nutrient solution stored in the waste nutrient solution storage tank 200, and to treat the concentrated nutrient solution stored in the nutrient solution concentration tank 400 after the treatment. Therefore, according to an embodiment of the present invention, a first valve (V1) is disposed between the waste nutrient solution storage tank (200) and the circulation pump (300) (Not shown) for controlling the opening and closing of the two valves, respectively, as shown in Fig. The valve control unit controls the second valve V2 to operate in a closed state while the first valve V1 is open and the second valve V2 is closed when treating the waste nutrient solution stored in the waste nutrient solution storage tank 200, , The first valve (V1) is closed and the second valve (V2) is operated in an open state.

Sterilization may be required in the pulp nutrient solution because it contains pollutants including microorganisms such as bacteria that reproduce in the cultivation tank. Such sterilization treatment is preferably performed before being stored in the waste nutrient solution storage tank. 1, an ozone sterilizer, an ultraviolet sterilizer, and the like may be added.

The results of the treatment using the waste nutrient separation apparatus according to one embodiment of the present invention described above will be described below.

FIG. 2 is a graph showing the electrical conductivity and the hydrogen ion concentration of the concentrated nutrient solution according to the concentration of the nutrient solution, and FIG. 3 is a graph showing the electrical conductivity and hydrogen ion concentration of the treated water according to the concentration of the nutrient solution.

A reverse osmosis membrane was used as a separation filtration membrane of the filtration unit 600, and the operation pressure of the circulation pump was maintained at 20 kgf / cm 2. The concentration and concentration of the concentrated nutrient solution treated by the above treatment conditions were re-enriched, and the amount of treatment until the nutrient solution was reduced by about 1/8 of the amount of the initial pulp nutrient solution, the water temperature change, the electric conductivity and the pH change of the concentrated nutrient solution, 3, respectively.

As a result of the test, as shown in FIG. 2, the electrical conductivity of the concentrated nutrient containing the nutrient solution component was 5.1 times higher at the initial 1.56dS / m to 8.0dS / m, and the pH tended to be 2.7% lower than the initial value It looked.

It was also confirmed that, in the case of water containing no nutrients, that is, treated water, as shown in Fig. 3, electrical conductivity increased and pH decreased.

From these test results, it can be confirmed that the better the degree of concentration of the waste nutrient solution is, the better the separation between the nutrient solution component and the water content is.

Next, the results of tests on the number of treatment of the waste nutrient solution, the separation performance of the nutrient separation apparatus according to the present invention, the electrical conductivity of the concentrated nutrient solution, and the pH at the same conditions will be described.

FIG. 4 is a graph showing the number of treatments of the waste nutrient solution and the treatment volume per unit time, and FIG. 5 is a graph showing changes in the electric conductivity and the pH of the concentrated nutrient solution.

As the number of treatments increases, the concentration of the nutrient solution component of the nutrient solution increases. As shown in FIG. 5, the electrical conductivity of the concentrated nutrient solution increases and the pH tends to decrease. This is similar to the relationship between the concentration and the concentration shown in FIG.

However, as shown in FIG. 5, the separation efficiency of the waste nutrient solution separation apparatus according to the present invention remains relatively uniform until the treatment of 6 times (190 to 200 l / h of the concentrated nutrient solution and 1,210 to 1,250 / h), and shows a tendency to deteriorate rapidly from the seventh time. Therefore, in the case of using the waste liquid nutrient separation apparatus according to the embodiment of the present invention, it is most efficient to carry out the number of repetitive processes six times.

Hereinafter, the results of the cultivation test using the concentrated nutrient solution separated by using the waste nutrient separation device according to the present invention will be described in detail.

First, test results using concentrated nutrient solution concentrated 25 times and 50 times by using the waste nutrient solution separating device of the present invention as extractant for cultivation of chestnuts will be described.

On February 22, pepper was sown on a 72 - tray tray and cultivated in a house equipped with electric heating. The formalities were 100 × 40cm after mulching with black PE vinyl in the packaging of the institute on April 29, N-P2O5-K2O-compost = 19.0-11.2-14.9-3,000 kg / 10a, Loto urea and Kali were divided into four treatments at a final concentration of 40% and 60%, respectively. The concentrated nutrient solution was applied 4 times according to the content of N in the amount of application. The amount of water in the waste water was the same as that in the conventional method. The placement of test specimens was done by repeating the nude method 3 times. Soil components were analyzed before and after the experiment to compare the changes of soil composition with application.

The root length of the pepper was 25.6cm, 3.4mm in diameter and 9.4 in number. The root length of the red pepper was 150.6cm in length, 27.7cm in length, 23.3mm in diameter, and 20.5 in number. There was no significant difference in the fresh juice of 25.8 times and 50 times of fresh juice by 153.8cm, 149.1cm, 27.2cm, 27.4cm, 22.9mm, 22.5mm, 20.7 and 20.2 respectively. The SPAD value for chlorophyll content was 65.1, which was not significantly different from 25.7 times for lung fluid and 63.5 for 50 times (Table 1).

Growth of red pepper according to concentrated nutrient solution division Super sheet
(cm) Main Street
(cm) Thoughts
(mm) Minute index
(dog) SPAD Before the test 25.0 3.4 N / A Administration 150.6 27.7 23.3 20.5 65.1 25 times 153.8 27.2 22.9 20.7 64.7 50 times 149.1 27.4 22.5 20.2 63.5

The fruit characteristics of pepper according to the treatments of the pulp nutrient solution during the hydroponic cultivation of lettuce midge were 15.2cm in exaggeration, 2.08cm in diameter, 2.18mm in thickness of flesh, 22.7g in fresh weight, and 25 times and 50 times There was no significant difference in the length of excretion between 14.9cm and 15.9cm, 2.07mm in diameter, 2.01mm in thickness, 2.21mm in thickness, 2.18mm in thickness, and 21.9g and 22.6g in fresh weight, respectively. The incidence of nodule rot or lime deficiency in fruit caused by poor absorption of lime ingredients in pepper cultivation was low at 5.3% and 6.3% in 25 times and 50 times of the waste nutrient solution by 7.2%, respectively. This is due to the fact that only nitrogen and carly components are dominant in the case of the practice, but the trace nutrients in the pulp nutrient include trace elements such as nitrogen, boron except for carly, and lime. The yield and yield of pepper were 3% and 6%, respectively, which was higher than that of 2,662kg / 10a (2,729kg / 10a) and 2,821kg / 10a (50%).

After the treatments and the concentrated nutrient solution were treated four times and the harvesting of the red pepper was completed, the chemical properties of the soil were pH 6.7, organic matter 39.9g / kg, effective phosphate 1,095mg / kg, carly 2.65cmol / kg, lime 9.5mol / kg, and magnesium of 3.96 cmol / kg, and the pH of the lettuce from 25 times and 50 times of the pH of the concentrated lung solution was 6.8 to 7.0, the organic matter of 44.0 to 44.2 g / kg, the effective phosphoric acid of 1,058 to 1,120 mg / kg, Lime 9.7 to 9.6 mol / kg, and magnesium 4.19 to 4.32 cmol / kg (Table 2). The chemical properties of the soil after the addition of concentrated nutrient solution of the lettuce mulberry juice cultivated in the pepper field were increased, but the amount of organic matter, phosphoric acid, and substitutional base t was increased at 25 times and 50 times, but there was no significant difference between treatments . Especially, phosphoric acid, which is a problem in the cultivation of vegetables, showed no significant difference between practice and pulmonary nutrient treatment. Therefore, it was concluded that recycling of waste nutrient solution does not have a big problem in soil compared to conventional fertilizer application.

Fruit Characteristics and Quantity of Red Pepper According to Concentrated Nutrient Solution Processing contents Exaggeration
(cm) Hyperbolic
(cm) Flesh thickness
(mm) Life
(g) Lime deficiency and
(%) Item number
(kg / 10a) Indices Administration 15.2 2.08 2.18 22.7 7.2 2,662 100 25 times 14.9 2.07 2.21 21.9 5.3 2,729 103 50 times 15.9 2.01 2.18 22.6 6.3 2,821 106

After the treatments and the concentrated nutrient solution were treated four times and the harvesting of the red pepper was completed, the chemical properties of the soil were pH 6.7, organic matter 39.9g / kg, effective phosphate 1,095mg / kg, carly 2.65cmol / kg, lime 9.5mol / kg, and magnesium of 3.96 cmol / kg, and the pH of the lettuce from 25 times and 50 times of the pH of the concentrated lung solution was 6.8 to 7.0, the organic matter of 44.0 to 44.2 g / kg, the effective phosphoric acid of 1,058 to 1,120 mg / kg, Lime 9.7 to 9.6 mol / kg, and magnesium 4.19 to 4.32 cmol / kg (Table 3).

Chemical properties of soils before and after testing according to nutrient solution division pH
(1: 5) OM
(g / kg) Avail.P ₂ O ₅
(mg / kg) Substitution base [cmol (+) / kg] Before the test 7.8 35.3 716 1.18 9.7 2.27 Practice 6.7 39.9 1,095 2.65 9.5 3.96 25 times 6.8 44.0 1,058 2.58 9.7 4.19 50 times 7.0 44.2 1,120 2.79 9.6 4.32

The chemical properties of the soil after the addition of concentrated nutrient solution of the lettuce mulberry juice cultivated in the pepper field were increased, but the amount of organic matter, phosphoric acid, and substitutional base t was increased at 25 times and 50 times, but there was no significant difference between treatments . Especially, phosphoric acid, which is a problem in the cultivation of vegetables, showed no significant difference between practice and pulmonary nutrient treatment. Therefore, it was concluded that recycling of waste nutrient solution does not have a big problem in soil compared to conventional fertilizer application.

As described above, according to the apparatus according to the present invention, it is possible to separate high-quality nutrients from the pulp nutrient solution, and it is economically effective because it can be used as a fertilizer for cultivating the house, as a fertilizer for house cultivation, or as a nutrient solution for hydroponics . In addition, unlike the conventional waste liquid treatment method, since the volume of the nutrient solution component can be reduced by increasing the concentration, the cost, time and labor required for transportation can be reduced.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood that various modifications and changes may be made thereto without departing from the spirit and scope of the invention.

100: Cultivation tank 200: Waste liquid storage tank
300: Circulation pump 400: Nitrogen concentration tank
500: Process water storage tank 600: Filtration section
V1: first valve V2: second valve

Claims (8)

A waste nutrient solution storage tank for storing a waste nutrient solution discharged from the cultivation tank;
A filtration unit for separating the nutrient solution component from the waste nutrient solution except for the nutrient solution component;
A circulation pump for supplying the waste nutrient solution from the waste nutrient solution storage tank to the filtration unit;
A nutrient liquid concentration tank for storing the nutrient solution component separated from the filtration unit; And
A processing water storage tank for storing the water separated from the filtration unit
/ RTI >
Wherein the filtration unit re-filters the nutrient solution components stored in the nutrient solution concentration tank over n times (n is a natural number greater than 1).
The waste nutrient separation device according to claim 1, wherein the filtration unit is a reverse osmosis filter.
The waste nutrient separation device according to claim 2, wherein the circulation pump operates so as to maintain a processing pressure of the filtration part at 20 kgf / cm 2.
4. The waste nutrient separation device according to claim 3, wherein n is 6.
5. The method according to any one of claims 1 to 4,
And a sterilizing unit for sterilizing the waste nutrient solution collected from the cultivation tank and supplying the sterilized waste solution to the waste nutrient solution storage tank.
6. The waste nutrient separation device according to claim 5, wherein the sterilizing unit is an ozone sterilizer.
5. The method according to any one of claims 1 to 4,
A first valve disposed between the waste nutrient solution storage tank and the circulation pump;
A second valve disposed between the nutrient solution concentration tank and the circulation pump; And
Further comprising a valve control section for controlling the opening and closing of the first valve and the second valve.
8. The method of claim 7,
Wherein the valve control unit controls the first valve to be in an opened state and the second valve to be in a closed state when the waste nutrient solution remains in the waste nutrient solution storage tank,
And controls the second valve to be in an open state while the first valve is closed when the waste nutrient solution does not remain in the waste nutrient solution storage tank.

Images