NL2026588B1 - Integrated agricultural irrigation and fertilizer application system - Google Patents

Abstract

The present invention discloses an integrated agricultural irrigation and fertilizer application system. The system comprises a water tank, a water collecting tank, fertilizer tanks, an acid solution tank, a chlorine solution tank, and a hydrogen peroxide tank. The water tank and the water collecting tank are connected. by the first water delivery pipe. A primary filter and the first water pump are sequentially arranged on the first water delivery pipe in a water flow direction. The water tank and the fertilizer tanks are connected by the second water delivery pipe. The second water pump is arranged on the second water delivery pipe. The water tank is also fixedly connected with one end of an irrigation main pipe. The third water pump is arranged on the irrigation main pipe. An irrigation branch pipe is communicated with a part, close to the end part, of the other end of the irrigation main pipe. A secondary filter is arranged on the irrigation branch pipe. The integrated agricultural irrigation and fertilizer application system of the present invention is provided with sprinkler irrigation pipes, drip irrigation pipes, nozzles, emitters, the acid solution tank, the chlorine solution tank, and the hydrogen peroxide tank to improve the irrigation effects and solve the problem that the internal pipeline and the emitters of the existing integrated agricultural irrigation and fertilizer application system are easy to be blocked.

Description

Integrated agricultural irrigation and fertilizer application system

TECHNICAL FIELD The present invention relates to the field of agricultural irrigation technologies, and specifically, to an integrated agricultural irrigation and fertilizer application system.

BACKGROUND Methods of agricultural irrigation can be generally divided into the traditional surface irrigation, the ordinary sprinkler irrigation, and the micro-irrigation. The traditional surface irrigation comprises border strip irrigation, furrow irrigation, basin irrigation, and flood irrigation, which often consume a lot of water and have low water utilization efficiency; so, they are a type of very unreasonable agricultural irrigation methods. The ordinary sprinkler irrigation is a popular irrigation method in agricultural production in China, but its water utilization efficiency is also low. The modern agricultural micro- irrigation comprises micro-sprinkler irrigation, drip irrigation, infiltration irrigation, etc. These irrigation technologies generally have good water-saving performance and higher water utilization efficiency compared with the traditional irrigation methods. Fertilizer application can also be carried out in the irrigation process. The process of fertilizers entering the field with irrigation water is called irrigation fertilizer application. Specifically, in the process of irrigation, such as drip irrigation, subsurface drip irrigation, etc., the fertilizers are accurately supplemented and evenly applied to near the root system according to the nutrient needs at various growth stages of the crop and the climatic conditions to be directly absorbed and utilized by the root system. However, the internal pipeline and the emitters of the existing integrated agricultural irrigation and fertilizer application system are easy to be blocked. So, it is necessary to improve the existing technology to solve the above problems.

- 2 =

SUMMARY I. The technical problem to be solved The objective of the present invention is to provide an integrated agricultural irrigation and fertilizer application system to solve the problem that the internal pipeline and the emitters of the existing integrated agricultural irrigation and fertilizer application system are easy to be blocked in the background. II. Technical solution To achieve the above objective, the present invention provides the following technical solution: an integrated agricultural irrigation and fertilizer application system comprises a water tank, a water collecting tank, fertilizer tanks, an acid solution tank, a chlorine solution tank, and a hydrogen peroxide tank. The water tank and the water collecting tank are connected by the first water delivery pipe. A primary filter and the first water pump are sequentially arranged on the first water delivery pipe in a water flow direction. The water tank and the fertilizer tanks are connected by the second water delivery pipe. The second water pump is arranged on the second water delivery pipe. The water tank is also fixedly connected with one end of an irrigation main pipe. The third water pump is arranged on the irrigation main pipe. An irrigation branch pipe is communicated with a part, close to the end part, of the other end of the irrigation main pipe. A secondary filter is arranged on the irrigation branch pipe. Sprinkler irrigation pipes and drip irrigation pipes are respectively connected with the upper side and the lower side of the irrigation branch pipe. A plurality of equidistantly distributed nozzles are arranged at the bottoms of the sprinkler irrigation pipes, and a plurality of equidistantly distributed emitters are arranged at the bottoms of the drip irrigation pipes. The acid solution tank is communicated with the irrigation main pipe through an acid feeding pipe, and an acid feeding pump is arranged on the acid feeding pipe. The chlorine solution tank is communicated with the irrigation main pipe through a chlorine feeding pipe, and a chlorine feeding pump is arranged on the chlorine feeding pipe. The hydrogen peroxide tank is communicated with the irrigation

- 3 = branch pipe through a hydrogen peroxide feeding pipe, and a hydrogen peroxide feeding pump is arranged on the hydrogen peroxide feeding pipe.

Preferably, there are three fertilizer tanks. Top inlets of the three fertilizer tanks are communicated with the second water delivery pipe. The bottoms of the fertilizer tanks are communicated with the irrigation main pipe through fertilizer delivery pipes.

Preferably, there are multiple sprinkler irrigation pipes and multiple drip irrigation pipes, and the multiple sprinkler irrigation pipes and the multiple drip irrigation pipes are respectively equidistantly arranged on the irrigation branch pipe in parallel.

Preferably, a flush valve is arranged at the end part of the other end of the irrigation main pipe.

Preferably, the acid solution tank is arranged at the upstream of the chlorine solution tank. The acid solution tank and the chlorine solution tank are arranged at the upstream of a connection part of the fertilizer delivery pipes and the irrigation main pipe.

Preferably, the hydrogen peroxide tank is arranged at the upstream of the secondary filter.

Preferably, the acid solution tank, the chlorine solution tank, and the hydrogen peroxide tank are connected with the water tank through the third water delivery pipes. The fourth water pump is arranged on each third water delivery pipe.

III. Beneficial effects Compared with the prior art, the present invention achieves the following beneficial effects: (1), In the present invention, the primary filter and the secondary filter are arranged. When the main pipeline is broken, or fine sands passing through the primary filter gather to form larger grains to cause a latent blockage threat, the secondary filter plays an important role. The primary filter and the secondary filter match with each other to greatly filter impurities in the water and help the pipes, the nozzles, the emitters, etc. to be unblocked.

(2), In the present invention, the sprinkler irrigation pipes, the drip irrigation pipes, the nozzles, and the emitters are

— 4 — arranged. In the fertilizer applying process, the fertilizers can be applied to the roots of the crops through the emitters.

In the irrigating process, the water can be transported to the roots of the crops through the emitters to irrigate the crops, and can also be sprinkled onto the leaves of the crops through the nozzles to conduct sprinkler irrigation on the crops. So, drip irrigation and sprinkler irrigation are combined to improve the irrigation effects.

(3), In the present invention, the acid solution tank, the chlorine solution tank, and the hydrogen peroxide tank are arranged to prevent the system from blocking. After the system is used for a period of time, organic sediments generated by bacteria, slime bacteria, and algae in the pipes can be treated by chemical agents to avoid blockage.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram showing the whole structure of the present invention.

FIG. 2 is a partially enlarged view of the present invention in FIG. 1.

FIG. 3 is a schematic diagram showing connection of a water tank and all material tanks in the present invention.

FIG. 4 is a sectional side view showing a position relationship of a sprinkler irrigation pipe and a drip irrigation pipe in the present invention.

Reference signs: 1l-water tank, 2-water collecting tank, 3- fertilizer tank, 4-first water delivery pipe, 5-primary filter, 6-first water pump, 7-second water delivery pipe, 8- second water pump, 9-irrigation main pipe, 10-third water pump, ll-secondary filter, 12-irrigation branch pipe, 13- sprinkler irrigation pipe, 14-drip irrigation pipe, 15-nozzle, l16-emitter, 17-fertilizer delivery pipe, 18-flush valve, 19- acid solution tank, 20-chlorine solution tank, 21-acid feeding pipe, 22-acid feeding pump, 23-chlorine feeding pipe, 24- chlorine feeding pump, 25-hydrogen peroxide tank, 26-hydrogen peroxide tank feeding pipe, 27-hydrogen peroxide tank feeding pump, 28-third water delivery pipe, and 29-fourth water pump.

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DESCRIPTION OF THE EMBODIMENTS The following clearly and completely describes the technical solutions in the embodiments of the present invention with reference to the accompanying drawings in the embodiments of the present invention. Apparently, the described embodiments are merely a part rather than all of the embodiments of the present invention. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present invention without creative efforts shall fall within the protection scope of the present invention. Referring to FIG. 1 to FIG. 4, in an embodiment provided by the present invention, an integrated agricultural irrigation and fertilizer application system comprises a water tank 1, a water collecting tank 2, fertilizer tanks 3, an acid solution tank 19, a chlorine solution tank 20, and a hydrogen peroxide tank 25. The water tank 1 and the water collecting tank 2 are connected by the first water delivery pipe 4. A primary filter 5 and the first water pump 6 are sequentially arranged on the first water delivery pipe 4 in a water flow direction. The water tank 1 and the fertilizer tanks 3 are connected by the second water delivery pipe 7. The second water pump 8 is arranged on the second water delivery pipe 7. The water tank 1 is also fixedly connected with one end of an irrigation main pipe 9. The third water pump 10 is arranged on the irrigation main pipe 9. An irrigation branch pipe 12 is communicated with a part, close to the end part, of the other end of the irrigation main pipe 9. A secondary filter 11 is arranged on the irrigation branch pipe 12, wherein the filter meshes of the primary filter 5 and the secondary filter 11 are the same, 120 meshes. Sprinkler irrigation pipes 13 and drip irrigation pipes 14 are respectively connected with the upper side and the lower side of the irrigation branch pipe 12; a plurality of equidistantly distributed nozzles 15 are arranged at the bottoms of the sprinkler irrigation pipes 13, and a plurality of equidistantly distributed emitters 16 are arranged at the bottoms of the drip irrigation pipes 14. The acid solution tank 19 is communicated with the irrigation main pipe 9 through an acid feeding pipe 21, and an acid feeding pump 22 is arranged on the acid feeding pipe 21. The chlorine solution

- 6 — tank 20 is communicated with the irrigation main pipe 3 through a chlorine feeding pipe 23, and a chlorine feeding pump 24 is arranged on the chlorine feeding pipe 23. The hydrogen peroxide tank 25 is communicated with the irrigation branch pipe 12 through a hydrogen peroxide feeding pipe 26, and a hydrogen peroxide feeding pump 27 is arranged on the hydrogen peroxide feeding pipe 26. Further, there are three fertilizer tanks 3. Top inlets of the three fertilizer tanks 3 are comunicated with the second water delivery pipe 7. The bottoms of the fertilizer tanks 3 are communicated with the irrigation main pipe 9 through fertilizer delivery pipes 17. A stirrer is arranged in each fertilizer tank 3 to uniformly stir the fertilizers in a fertilizer applying process. The fertilizer tanks 3 and the water tank 1 are connected by the second water delivery pipe

7. So, a mixed fertilizer solution can be prepared from the clean water in the water tank 1 and the fertilizer. The preparation of the fertilizer is also convenient. Further, there are multiple sprinkler irrigation pipes 13 and multiple drip irrigation pipes 14, and the multiple sprinkler irrigation pipes 13 and the multiple drip irrigation pipes 14 are respectively equidistantly arranged on the irrigation branch pipe 12 in parallel. The water can be sprayed from the nozzles 15 to irrigate the leaves of the crops and can also be dripped from the emitters 16 to irrigate the roots of the crops. So, drip irrigation, sprinkler irrigation, or their combination can be selected as required. Further, a flush valve 18 is arranged at the end part of the other end of the irrigation main pipe 9. The flush valve 18 can be externally connected with a flushing device to flush the system. Further, the acid solution tank 19 is arranged at the upstream of the chlorine solution tank 20. When the pH value of the chlorine solution is higher than 7.0, the chlorine solution basically is ineffective; so, it is necessary to conduct the acid treatment by the acid solution tank 19 to complete the chlorine treatment downstream. Additionally, the acid solution tank 19 and the chlorine solution tank 20 are arranged at the upstream of a connection part of the fertilizer delivery pipes

- 7 = 17 and the irrigation main pipe 3.

Further, the hydrogen peroxide tank 25 is arranged at the upstream of the secondary filter 11 to process the secondary filter 11.

Further, the acid solution tank 19, the chlorine solution tank 20, and the hydrogen peroxide tank 25 are connected with the water tank 1 through the third water delivery pipes 28. The fourth water pump 29 is arranged on each third water delivery pipe 28.

Specific using steps of the system are as follows: Sl: The first water pump 6 pumps water {from the water collecting tank 2 to the water tank 1 for later use, and the water is filtered by the primary filter 5.

S2: When the crops need to be irrigated, the third water pump 10 starts. Under the action of the third water pump 10, the water in the water tank 1 {flows into the secondary filter 11 through the irrigation main pipe 3 to be filtered. The filtered water flows into the sprinkler irrigation pipes 13 and the drip irrigation pipes 14 through the irrigation branch pipe 12, and then is sprayed through the nozzles 15 to irrigate the leaves of the crops and dripped through the emitters 16 to irrigate the roots of the crops. Drip irrigation, sprinkler irrigation, or their combination can be selected as required.

S3: When the crops need fertilizer application, a mixed fertilizer solution is prepared. The second water pump 8 pumps the clean water from the water tank 1 to the fertilizer tanks 3. Solid fertilizers are putted into the fertilizer tanks 3 to form mixers. The stirrers mix the mixers uniformly to obtain the mixed fertilizer solutions. The third water pump 10 starts. Under the action of the third water pump 10, the mixed fertilizer solutions in the fertilizer tanks 3 flow into the secondary filter 11 through the irrigation main pipe 9 to be filtered. The filtered fertilizer solution flows into the drip irrigation pipes 14 through the irrigation branch pipe 12, and then is dripped through the emitters 16 to apply the fertilizers to the roots of the crops.

- 8 - S4: After the system is used for a period of time, organic sediments generated by bacteria, slime bacteria, and algae in the pipes need to be treated. The acid treatment is conducted firstly. A qualified acid solution is prepared in the acid solution tank 19, wherein the pH value is reduced in the range of 5 and 6. The acid feeding pump 22 {feeds the prepared acid solution into the system. Next, the chlorine treatment is conducted. The chlorine feeding pump 24 feeds the chlorine treatment solution into the system until 1-3 ppm of available chlorine can be measured from the liquid dripped by the emitters 16. Then, the interior treatment of the pipes and the emitters 16 can be conducted.

S5: When the conventional chlorine treatment is ineffective, the problem may be solved by utilizing hydrogen peroxide. The hydrogen peroxide has the better effect to treat the sediments in the pipes compared with the chlorine. The hydrogen peroxide feeding pump 27 feeds the hydrogen peroxide into the system. The hydrogen peroxide keeps feeding, and 100 ppm of the hydrogen peroxide treatment solution can be obtained from feeding points until the liquid dripped by the emitters 16 starts bubbling. Then, the interior treatment of the pipes and the emitters 16 can be conducted.

Working principle is as follows: the system can simultaneously have the irrigation function and the fertilizer application function due to the arrangement of the water tank 1 and the multiple fertilizer tanks 3. The integrated design helps the whole system easy to be maintained. The agricultural irrigation and fertilizer application is simpler.

Additionally, the fertilizer tanks 3 and the water tank 1 are connected by the second water delivery pipe 7; so, the clean water in the water tank 1 can be used for preparing the mixed fertilizer solution, and the preparation of the fertilizer is also convenient. Furthermore, the primary filter 5 and the secondary filter 11 are arranged. When the main pipeline is broken, or fine sands passing through the primary filter 5 gather to form larger grains to cause a latent blockage

- 9 — threat, the secondary filter 11 plays an important role. The primary filter 5 and the secondary filter 11 match with each other to greatly filter impurities in the water and help the pipes, the nozzles 15, the emitters 16, etc. to be unblocked. Moreover, the sprinkler irrigation pipes 13, the drip irrigation pipes 14, the nozzles 15, and the emitters 16 are arranged. In the fertilizer applying process, the fertilizers can be applied to the roots of the crops through the emitters

16. In the irrigating process, the water can be transported to the roots of the crops through the emitters 16 to irrigate the crops, and can also be sprinkled onto the leaves of the crops through the nozzles 15 to conduct sprinkler irrigation on the crops. So, drip irrigation and sprinkler irrigation are combined to improve the irrigation effects. And, the acid solution tank 19, the chlorine solution tank 20, and the hydrogen peroxide tank 25 are arranged to prevent the system from blocking. After the system is used for a period of time, the organic sediments generated by bacteria, slime bacteria, and algae in the pipes can be treated by chemical agents to avoid blockage. It should be noted that the use of relational terms herein, such as first and second and the like, are used solely to distinguish one entity or action from another without necessarily requiring or implying any actual relationship or order between such entities or actions. Furthermore, the terms “comprises,” “comprising,” or any variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Although the embodiments of the present invention have been illustrated and described, it should be understood that those of ordinary skill in the art may make various changes, modifications, replacements and variations to the above embodiments without departing from the principle and spirit of the present invention, and the scope of the present invention is limited by the appended claims and their legal equivalents.

- 10 = Aspects of the invention are itemized in the following section.

1. An integrated agricultural irrigation and fertilizer application system, comprising a water tank (1), a water collecting tank (2), fertilizer tanks (3), an acid solution tank (19), a chlorine solution tank (20), and a hydrogen peroxide tank (25), wherein the water tank (1) and the water collecting tank (2) are connected by the first water delivery pipe (4); a primary filter (5) and the first water pump (6) are sequentially arranged on the first water delivery pipe (4) in a water flow direction; the water tank (1) and the fertilizer tanks (3) are connected by the second water delivery pipe (7); the second water pump (8) is arranged on the second water delivery pipe (7); the water tank (1) is also fixedly connected with one end of an irrigation main pipe (9); the third water pump (10) is arranged on the irrigation main pipe (9); an irrigation branch pipe (12) is communicated with a part, close to the end part, of the other end of the irrigation main pipe (9); a secondary filter (11) is arranged on the irrigation branch pipe (12); sprinkler irrigation pipes (13) and drip irrigation pipes (14) are respectively connected with the upper side and the lower side of the irrigation branch pipe (12); a plurality of equidistantly distributed nozzles (15) are arranged at the bottoms of the sprinkler irrigation pipes (13), and a plurality of equidistantly distributed emitters (16) are arranged at the bottoms of the drip irrigation pipes (14); the acid solution tank (19) is communicated with the irrigation main pipe (9) through an acid feeding pipe (21), and an acid feeding pump (22) is arranged on the acid feeding pipe (21); the chlorine solution tank (20) is communicated with the irrigation main pipe (9) through a chlorine feeding pipe (23), and a chlorine feeding pump (24) is arranged on the chlorine feeding pipe (23); the hydrogen peroxide tank (25) is communicated with the irrigation branch pipe (12) through a hydrogen peroxide feeding pipe (26), and a hydrogen peroxide feeding pump (27) is arranged on the hydrogen peroxide feeding pipe (26).

2. The integrated agricultural irrigation and fertilizer application system according to claim 1, wherein

- 11 - there are three fertilizer tanks (3); top inlets of the three fertilizer tanks (3) are communicated with the second water delivery pipe (7); the bottoms of the fertilizer tanks (3) are communicated with the irrigation main pipe (9) through fertilizer delivery pipes (17).

3. The integrated agricultural irrigation and fertilizer application system according to claim 1, wherein there are multiple sprinkler irrigation pipes {13) and multiple drip irrigation pipes (14), and the multiple sprinkler irrigation pipes (13) and the multiple drip irrigation pipes (14) are respectively equidistantly arranged on the irrigation branch pipe (12) in parallel.

4. The integrated agricultural irrigation and fertilizer application system according to claim 1, wherein a flush valve (18) is arranged at the end part of the other end of the irrigation main pipe (9).

5. The integrated agricultural irrigation and fertilizer application system according to claim 1, wherein the acid solution tank (19) is arranged at the upstream of the chlorine solution tank (20); the acid solution tank (19) and the chlorine solution tank (20) are arranged at the upstream of a connection part of the fertilizer delivery pipes (17) and the irrigation main pipe (9).

6. The integrated agricultural irrigation and fertilizer application system according to claim 1, wherein the hydrogen peroxide tank (25) is arranged at the upstream of the secondary filter (11).

7. The integrated agricultural irrigation and fertilizer application system according to claim 1, wherein the acid solution tank (19), the chlorine solution tank (20), and the hydrogen peroxide tank (25) are connected with the water tank (1) through the third water delivery pipes (28); the fourth water pump (29) is arranged on each third water delivery pipe (28).

Claims (7)

- 12 — CONCLUSIONS An integrated agricultural irrigation and fertilizer system, comprising a water tank (1), a water collecting tank (2), fertilizer tanks (3), an acid solution tank (19), a chlorine solution tank (20) and a hydrogen peroxide tank (25), wherein the water tank (1) and the water receiving tank (2) are connected by a first water delivery line (4); a primary filter (5) and a first water pump (6) are sequentially arranged on a first water delivery line (4) in a water flow direction; the water tank (1) and the fertilizer tanks (3) are connected by a second water discharge pipe (7); a second water pump (8) is arranged on a second water discharge line (7); the water tank (1) is also fixedly connected to one end of an irrigation main line (9); a third water pump (10) is mounted on an irrigation main line (9); an irrigation branch conduit (12) in communication with a portion, near the end portion, of the other end of the irrigation trunk conduit (9); a secondary filter (11) is mounted on the irrigation branch line (12); sprinkler irrigation pipes (13) and drip irrigation pipes (14) are respectively connected to a top and a bottom of the irrigation branch pipe (12); a plurality of equidistantly distributed nozzles (15) are disposed at the bottoms of the sprinkler irrigation lines (13), and a plurality of equidistantly distributed emitters (16) are disposed at the bottoms of the drip irrigation lines (14); the acid solution tank (19) is in communication with the main irrigation line (9) through an acid supply line (21), and an acid supply pump (22) is provided on the acid supply line (21); the chlorine solution tank (20) is in communication with the main irrigation line (9) through a chlorine supply line (23), and a chlorine supply pump (24) is mounted on the chlorine supply line (23); the hydrogen peroxide tank (25) is in communication with the irrigation branch line (12) through a hydrogen peroxide supply line (26), and a hydrogen peroxide supply pump (27) is provided on the hydrogen peroxide supply line (26). - 13 = An integrated agricultural irrigation and fertilizer system according to claim 1, wherein there are three fertilizer tanks (3); the upper inlets of the three fertilizer tanks (3) communicate with the second water discharge pipe (7); the bottoms of the fertilizer tanks (3) are connected to the main irrigation pipe (9) via fertilizer discharge pipes (17). The integrated agricultural irrigation and fertilizer system according to claim 1, wherein there are a plurality of sprinkler irrigation lines (13) and a plurality of drip irrigation lines (14), and the multiple sprinkler irrigation lines (13) and the multiple drip irrigation lines (14) are respectively equidistantly arranged in parallel on the irrigation branch line. (12). An integrated agricultural irrigation and fertilizer system according to claim 1, wherein a flush valve (18) is provided at the end portion of the other end of the main irrigation pipe (9). The integrated agricultural irrigation and fertilizer system according to claim 1, wherein the acid solution tank {19) is arranged upstream of the chlorine solution tank (20); the acid solution tank (19) and the chlorine solution tank (20) are arranged upstream of a connecting portion of the fertilizer discharge pipes (17) and the main irrigation pipe (9). An integrated agricultural irrigation and fertilizer system according to claim 1, wherein the hydrogen peroxide tank (25) is arranged upstream of the secondary filter (11). The integrated agricultural irrigation and fertilizer system according to claim 1, wherein the acid solution tank (19), the chlorine solution tank (20) and the hydrogen peroxide tank (25) are connected to the water tank (1) through the third water discharge pipes (28); the fourth water pump {29) is mounted on every third water supply line (28).