ES1323148U - Fertigation equipment (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Equipment for fertigation, for agricultural installations comprising an irrigation manifold (1), an irrigation pump (2) and a filtering mechanism (3) connected to the irrigation manifold (1), and one or more injection lines (4) of fertilizers or acids into the irrigation water, characterized in that it is connected to the irrigation manifold (1) by means of a first bypass (5) comprising an inlet manifold (6) to the equipment connected downstream of the filtering mechanism (3) and an outlet manifold (7) of the equipment connected upstream of the filtering mechanism (3), and comprises - control means (24); - one or more fertigation modules (8) connected to an injection line (4) each, where each module (8) comprises a first connection line (11) between the inlet manifold (6) and the outlet manifold (7) comprising a Venturi injector (13), and; a second conduit (12) for connecting one of the injection lines (4) to the Venturi injector (13), comprising a dosage control solenoid valve (14) connected to the control means (24); - a second bypass (9) formed by a probe manifold (10) comprising a pH probe (18) and an electrical conductivity probe (19) connected to the control means (24), where this probe manifold (10) has a connection to the inlet manifold (6) and a connection to the outlet manifold (7), located upstream and downstream of the first conduit (11) respectively, and; - a frame (23) for supporting the previous elements. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Fertigation equipment

Technical field of the invention

The present invention corresponds to the technical field of agriculture, specifically to a fertigation equipment applicable to agricultural facilities, both outdoors and in greenhouses.

Background of the Invention

Fertigation is a technique that allows the application of nutrient solutions and chemicals to crops during the irrigation process, achieving a precise and controlled application of nutrients directly to the active root zone of the plants.

This technique makes it possible to considerably reduce the consumption of both water and fertilizers, simplifies some agricultural tasks, saves on maintenance costs, and considerably reduces soil compaction and erosion.

However, it also has certain drawbacks, as this solution often requires an injection pump for each line of fertilizer or acid to be injected, which implies a higher installation cost, maintenance cost, and higher energy consumption.

Furthermore, precise dosing often requires complex control systems that make these types of techniques more expensive.

As an example of the state of the art, we can mention reference document ES2047433 (Martínez Matías, José Manuel), which describes an integrated fertigation unit consisting of tanks that store concentrated fertilizers inside, which are mixed with water, and which are injected into the irrigation pipe itself through conduits, valves and pumps that make up a complete hydraulic circuit.

This circuit, after each use in irrigation, needs to be cleaned with acidified water stored in a tank for this purpose. A central control unit for the entire system has been provided, which has a sound alarm system that warns of any external tampering and when any of the tanks contains fertilizer below 20% of its capacity. One or more of these fertilization units can be connected to a community irrigation control center for all of them.

The problem, as already mentioned, is that each of the fertilizers requires the corresponding injection pump, which means a large number of pumps in the system, one for each injection line, as well as other mechanical components, with the consequent cost that this entails.

It is necessary to find a way to approach the fertigation technique with mechanisms that do not require multiple injection pumps and allow precise control of fertilizer injection that can be easily configured according to the needs of the crop.

Description of the invention

The fertigation equipment presented here is applicable to agricultural installations comprising an irrigation manifold, an irrigation pump and a filtration mechanism connected to the irrigation manifold, as well as one or more lines for injecting fertilizers or acids into the irrigation water.

This equipment proposed here is connected to the irrigation manifold by means of a first bypass comprising an inlet manifold to the connected equipment downstream of the filtering mechanism and an outlet manifold from the connected equipment upstream of the filtering mechanism.

The fertigation equipment comprises control means and one or more fertigation modules connected to an injection line each.

It also includes a second bypass consisting of a probe manifold with a pH probe and an electrical conductivity probe connected to the control system. This probe manifold has a connection to the inlet manifold and a connection to the outlet manifold, located upstream and downstream of the first pipeline, respectively.

The equipment also features a support frame for the aforementioned elements.

For its part, each of the fertigation modules comprises a first connection conduit between the inlet manifold and the outlet manifold comprising a Venturi injector, and a second connection conduit from one of the injection lines to said Venturi injector, comprising a dosage control solenoid valve connected to the control means.

The fertigation equipment proposed here represents a significant improvement over the state of the art.

This is because the fertilizer or acid is incorporated by suction through the Venturi injector, at its smallest section point, thus achieving a passive and precise injection that eliminates the need for individual pumps for each fertilizer or acid to be injected.

This reduces energy and maintenance costs for pumps and other hydraulic components that are no longer needed in this equipment.

Furthermore, this equipment features automatic pH and electrical conductivity control probes in real time, as well as control means connected to the fertigation modules that allow adjusting the amounts to be injected at any time according to the needs and according to the values obtained in the sensors.

This makes it very easy to modify the injection configuration of the different fertilizers and acids, allowing the equipment to be adapted to different configurations.

It is, therefore, a piece of equipment that brings autonomy to the process, automating the supply of water and nutrients so that irrigation is carried out completely autonomously without direct human intervention to make the supplies with the required frequency and duration.

Furthermore, with this equipment it is not necessary to prepare a stock solution beforehand with a specific amount of each fertilizer, but it is possible to apply fertilizers simultaneously, allowing for more versatile and dynamic nutrition by being able to independently adjust the nutrient balance required by each of the irrigation sectors.

By achieving precise control of the unit quantity and the desired nutrient balance, greater profitability is obtained from the fertilizers supplied, with less loss due to percolation, higher absorption rates due to the high moisture present in the active root zone and the possibility of adapting the pH level to the optimal values that guarantee greater absorption.

Another very important advantage is the fact that it is a modular, compact and accessible piece of equipment, which allows adding more or fewer fertigation modules depending on the number of fertilizers and acids that need to be added to the crop, and it is all contained in a support frame that occupies a small space.

It is therefore a very effective fertigation system that solves the problems that exist today.

Brief description of the drawings

In order to aid a better understanding of the characteristics of the invention, according to a preferred embodiment thereof, a series of drawings are provided as an integral part of this description, where, for illustrative and non-limiting purposes, the following has been represented:

Figure 1 shows a profile view of a fertigation module of a fertigation equipment, for a first preferred embodiment of the invention.

Figure 2 shows a schematic of the installation of a fertigation equipment, for a first preferred embodiment of the invention.

Figure 3 shows a schematic of the installation of a fertigation equipment, for a second preferred embodiment of the invention.

Detailed description of a preferred embodiment of the invention

In view of the figures provided, it can be observed how, in a first preferred embodiment of the invention, the fertigation equipment proposed herein is suitable for agricultural installations comprising an irrigation manifold (1), an irrigation pump (2) and a filtration mechanism (3) connected to the irrigation manifold (1), and one or more injection lines (4) of fertilizers or acids into the irrigation water.

As shown in Figure 2, this equipment is connected to the irrigation manifold (1) by means of a first bypass (5) comprising an inlet manifold (6) to the equipment connected downstream of the filtering mechanism (3) and an outlet manifold (7) from the equipment connected upstream of the filtering mechanism (3).

This equipment comprises control means (24), one or more fertigation modules (8), each of which is connected to an injection line (4), a second bypass (9) consisting of a probe manifold (10) and a frame (23) supporting all these elements.

In this first embodiment, the support frame (23) is formed by a table-like structure that has all the hydraulic components of the fertigation equipment at the bottom and the control means components (24) are located at the top.

As shown in Figure 1, in this first preferred embodiment, the equipment comprises three fertigation modules (8), each comprising a first connecting pipe (11) between the inlet manifold (6) and the outlet manifold (7), which includes a Venturi injector (13), and a second connecting pipe (12) between one of the injection lines (4) and the Venturi injector (13). Each injection line (4) is connected to a fertilizer or acid storage tank. In this first embodiment, two fertilizer tanks (21) and one acid tank (22) are considered.

This second connection conduit (12) comprises a dosing control solenoid valve (14) connected to the control means (24).

In this first preferred embodiment of the invention, this second conduit (12) further comprises a non-return valve (15) in the connection to the Venturi injector (13).

Likewise, in this first embodiment, the second pipe (12) also features an inclined seat valve (16) for manual flow control and a float gauge (17) for measuring the flow rate of each line. However, these elements may not be included in other embodiments.

Furthermore, the probe manifold (10) of the second bypass (9) comprises a pH probe (18) and an electrical conductivity probe (19) connected to the control means (24). This probe manifold (10) has a connection to the inlet manifold (6) and a connection to the outlet manifold (7), located upstream and downstream of the first pipeline (11) respectively.

Thus, the operation of the equipment begins by diverting part of the irrigation water circulating through the irrigation collector (1) to the first bypass (5).

Of the diverted water flowing through the inlet manifold (6) to the equipment, a portion is diverted through the second bypass (9) to take readings via the pH (18) and electrical conductivity (19) probes. Using these readings, and with the help of a controller that is part of the control system (24), the required amount of each type of fertilizer to be injected into each of the fertigation modules (8) is determined. This injection is carried out via the outlet manifold (7) of the equipment, which forms the first bypass (5).

The entire mixture of injected fertilizers or acids reaches the irrigation manifold (1) at a point upstream of the filtration mechanism (3) and is then homogenized within said mechanism before being distributed to the irrigation sectors, and the cycle begins again.

In this new cycle, a portion of the water volume with the applied and mixed fertilizer concentration that is directed towards the irrigation sectors is again diverted through the first bypass (5), because as a volume of water that circulated through the irrigation manifold (1) has been added, the fertilizer concentration is diluted a little, and therefore it is necessary to take measurements again with the probes and, according to the measurements obtained, corrections must be made to the quantities to be injected.

These operations are performed continuously, and this configuration ensures that all necessary adjustments are continuously being made to obtain a fixed pH and electrical conductivity at the outlet of the irrigation manifold (1) to the crops.

As shown in Figure 2, in this first preferred embodiment of the invention, the equipment comprises an auxiliary pump (20) connected to the outlet manifold (7) downstream of the second bypass (9). This auxiliary pump (20) propels the resulting mixture of irrigation water and fertilizers through the outlet manifold (7) into the irrigation manifold (1) at a point thereup of the filtration mechanism (3), so that it mixes with the remaining irrigation water inside the filtration mechanism (3).

In other embodiments, such as the second one shown in Figure 3, the equipment does not have an auxiliary pump (20). Instead, in this case, the irrigation pump (2) is made of stainless steel and is capable of directly drawing the mixture obtained by the equipment, which consists of a portion of the irrigation water and fertilizers. This irrigation pump (2) draws directly from the irrigation manifold (1) and through the outlet manifold (7) of the first bypass (5).

In this case, a stainless steel irrigation pump (2) is considered in order to withstand prolonged contact with chemical solutions.

Claims (1)

1- Fertigation equipment for agricultural installations comprising an irrigation manifold (1), an irrigation pump (2), and a filtration mechanism (3) connected to the irrigation manifold (1), and one or more injection lines (4) for fertilizers or acids in the irrigation water, characterized in that it is connected to the irrigation manifold (1) by means of a first bypass (5) comprising an inlet manifold (6) to the equipment connected downstream of the filtration mechanism (3) and an outlet manifold (7) from the equipment connected upstream of the filtration mechanism (3), and comprises - some means of control (24); - one or more fertigation modules (8) connected to an injection line (4) each, where each module (8) comprises • a first connecting conduit (11) between the inlet manifold (6) and the outlet manifold (7) comprising a Venturi injector (13), and; • a second conduit (12) connecting one of the injection lines (4) to the Venturi injector (13), comprising a dosage control solenoid valve (14) connected to the control means (24); - a second bypass (9) formed by a probe manifold (10) comprising a pH probe (18) and an electrical conductivity probe (19) connected to the control means (24), wherein this probe manifold (10) has a connection to the inlet manifold (6) and a connection to the outlet manifold (7), located upstream and downstream of the first conduit (11) respectively, and; - a support frame (23) for the above elements. 2- Equipment according to claim 1, comprising an auxiliary pump (20) connected to the outlet manifold (7) downstream of the second bypass (9). 3- Equipment according to claim 1, wherein the irrigation pump (2) is made of stainless steel and is capable of sucking the mixture obtained by the equipment through the outlet manifold (7). 4- Equipment according to any of the preceding claims, wherein the second conduit (12) is connected to the Venturi injector (13) by means of a non-return valve (15). 5- Equipment according to any of the preceding claims, wherein the second conduit (12) comprises an inclined seat valve (16) for manual flow control. 6- Equipment according to any of the preceding claims, wherein the second conduit (12) comprises a floatometer (17) for measuring the flow rate of each line.