WO2018176113A1

WO2018176113A1 - Device applied to equipment with an electric diaphragm metering pump for controlling the injection of fertilizers into irrigation systems

Info

Publication number: WO2018176113A1
Application number: PCT/BR2018/050082
Authority: WO
Inventors: Enison Roberto POZZANI
Original assignee: Pozzani Enison Roberto
Priority date: 2017-03-27
Filing date: 2018-03-26
Publication date: 2018-10-04
Also published as: BR202017006237Y1; BR202017006237U2

Abstract

The invention relates to an item of equipment (1) that basically comprises a rack (R), composed of piping (T), which comprises a manifold (3) that mixes water (A) and fertilizers (F) by means of an injection pump (BJ) that injects water (A) into the manifold (3), and electric diaphragm metering pumps (10) that suck the fertilizers into the manifold (3) for subsequent dispersion to an irrigation system (IR); the invention may be installed as a by-pass on a main irrigation line (LI) and be installed as a by-pass with the motorized irrigation pump (MI).

Description

ARRANGEMENT APPLIED TO ELECTRICAL DIAPHRAGM DOSING PUMP EQUIPMENT FOR FERTILIZER INJECTION CONTROL

IRRIGATION SYSTEMS

[001] This report describes the Utility Model Patent Application of an unpublished "PROVISION APPLIED ON ELECTRICAL DIAPHRAGM DOSING PUMP FOR IRRIGATION SYSTEMS INJECTION" which in turn comprises equipment to control the dosage of fertilizer injection into an irrigation system, which by means of components such as a manifold; PH probe; Retention valve; rotameter; pressure gauge; solenoid valve, and electric diaphragm metering pumps, enable continuous and stable dosing of said liquid fertilizers together in water in agricultural crops, and provide longer life.

APPLICATION FIELD

[002] The equipment with electric diaphragm metering pump for fertilizer injection control in irrigation system has its application field facing the fertirrigation field, commonly used in agriculture, sports lawns and landscaping irrigation.

CONVENTION

It is known that there are several fertigation control equipments (application of liquid fertilizers in the irrigation) in the market, and these equipments use a Venturi type device to generate negative pressure in order to suck the liquid fertilizers; There are several Venturis to inject different types of fertilizer into an irrigation system. Fertilizer dosage control in this case is done by opening and closing the Venturi suction with appropriate frequency by means of electric valves (solenoids).

[004] These equipments have a probe to measure the electrical conductivity (EC) and another to measure the pH of the solution that goes to irrigation, in order to keep within previously adjusted parameters, in this case the EC, the PH and the proportion of the different fertilizers that make up the fertilizer recipe. However, the Venturi injection system interferes with the fertilizer suction rate as the Fertilizer tank level due to pressure variation at the Venturi suction inlet, the fertilizer dosage control is done by opening and closing the Venturi suction through a solenoid valve, ie an ON-OFF control, this intermittency causes dosing to fluctuate electrical conductivity in the irrigation pipe after fertilizer injection and oscillating sample reading, which makes system stability difficult.

[005] The solenoid valves used in this system are costly because they must meet certain technical characteristics such as durability, chemical resistance and quick actuation. Venturis uses cause a large loss of pressure in the irrigation line, as all water flows through the venturi and this requires the use of a "booster" pump to replace the pressure loss in the line, which again makes the equipment more expensive. .

[006] Other commercially available equipment injects fertilizers through an electric piston pump, which is commonly used in agricultural spraying, adapted for the purpose of injecting fertilizers into the irrigation line, and dosage control is done by frequency converter that alters the speed of the electric motor and hence the fertilizer injection rate to maintain EC control as desired. In this system, the pump has two or three pistons and each is used for one type of fertilizer and the injection rate is fixed for all pistons, ie there is no way to vary the ratio between all fertilizers, and the system has high cost. Another very common system is the use of hydraulic metering pumps, which dose proportionally to the water flow but are metered by manual regulation without EC measurement or control in the line.

CURRENT STATE OF TECHNIQUE

[007] The current state of the art anticipates some patent documents dealing with the subject matter such as DOCUMENT: MU 7100555-2 U2 - DATE OF DEPOSIT: 20/05/1991 TITLE: "TYPE VENTURI INJECTOR". SUMMARY: This refers to an equipment that aims to simplify the system operation with reduction of the final cost. The equipment allows the automation of the lift and the suppression of difficult and constant maintenance equipment. The equipment basically consists of in galvanized iron pipe system (variable diameter) automatic stop registration (solenoid and manual valve - gate registration) with galvanized iron venture-type throttle tube inside the pipe. All threads must be turned using a suitable thread seal, allowing sufficient protection and sealing for the working pressure.

[008] The model described above reveals a Venturi-type injector which, as already mentioned above, when intended for the irrigation system, interferes with the fertilizer suction rate as the fertilizer tank level varies due to inlet pressure variation. Venturi suction.

PURPOSE OF THE NEW MODEL

[009] The present innovation aims to propose an equipment which by means of a set of components, such as a manifold; PH probe; Retention valve; rotameter; pressure gauge; solenoid valve; and a set of electric diaphragm metering pumps enables continuous and stable dosing of fertilizers in affordable, low-maintenance crop irrigation systems.

THE NEW MODEL

[010] Aware of the state of the art, its shortcomings and limitations, the inventor, after studies and research has created the APPLIED APPLICATION FOR ELECTRICAL DIAPHRAGM DOSING PUMP FOR IRRIGATION SYSTEMS INJECTION "which refers to an equipment comprised of an aluminum rack, which houses a command box on its top, with interface through keyboard and graphic display, which is responsible for controlling the system steps through hardware, firmware, and software; electrical panel arranged on the front of the aluminum rack, responsible for the electrical part of the equipment.

[01 1] The equipment basically consists of a manifold responsible for the movement of water, as well as the junction of the other tubular parts of the equipment, and the manifold contains openings and connections to the system, which generally has several components. as a pH probe, responsible for measuring the pH of water, and other parameters in the equipment; an check valve, used to allow water to flow in one direction of the pipe and block it in the opposite direction; a rotameter used to measure water flow in the pipeline; an EC probe, which measures the temperature compensated electrical conductivity of the equipment system, where it is connected to the EC meter located on the electrical board; a nozzle responsible for the water entering the system through a pipe that connects to an irrigation pump that picks up water from a water box and brings the water to that manifold.

[012] In short, the equipment receives water through the inlet nozzle, which goes through the EC probe, then through the rotameter, then through the PH probe and then through the check valve, until it reaches the fertilizer injection points, where the manifold presents the pipeline connections connected to the electric diaphragm dosing pumps, which comprise ducts connected to fertilizer filters, thus the electric diaphragm dosing pumps are responsible for sucking fertilizers arranged in reservoirs and carrying the fertilizers up to the manifold, which finally features a monometer, and a solenoid valve an "L" pipe fitted with a water outlet nozzle mixed with the fertilizers in the manifold, and then dispersed in an irrigation system.

[013] Therefore, the improvement in question is made by means of the whole structure composed by the components described above, as well as the electric diaphragm metering pumps which, in contrast to the current state of the art systems that are oscillating, costly. and unstable, the electric diaphragm metering pump injects directly into the irrigation line continuously, ie stable, dry working without risk of damage, do not require lubrication or cleaning for years and when this is necessary, They are easily removable for cleaning.

Finally, the present innovation comprises two modes of installations, which at first is bypassed on the main irrigation line, and a second moment is bypassed with the irrigation motor pump.

DESCRIPTION OF THE FIGURES The innovation will hereinafter be described in a preferred embodiment, and for better understanding references will be made to the accompanying drawings, in which they are illustrated by way of illustration and not limitation:

Figure 1: Perspective view of equipment with electric diaphragm metering pump for fertilizer injection control in an irrigation pumping system;

Figure 2: Inverted perspective view of the electric diaphragm metering pump equipment for fertilizer injection control in an irrigation pumping system;

Figure 3: Perspective view of equipment with electric diaphragm metering pump for fertilizer injection control in an irrigation pumping system showing equipment components outside the aluminum frame;

Figure 4: Schematic view of equipment with electric diaphragm metering pump for fertilizer injection control in an irrigation pumping system, showing the bypass installation on the main irrigation line;

Figure 5: Schematic view of the electric diaphragm metering pump equipment for fertilizer injection control in an irrigation pumping system, showing the bypass installation with the irrigation motor pump.

DETAILED DESCRIPTION OF THE NEW MODEL

[016] THE APPLICATION APPLIED TO ELECTRICAL DIAPHRAGM DOSING PUMP EQUIPMENT FOR FERTILIZER INJECTION CONTROL IN IRRIGATION SYSTEMS, which refers to equipment (1) which basically consists of a rack (R), consisting of a tubing (T) composed of a manifold (3) that mixes water (A) and fertilizer (F) by means of an injection pump (BJ) that injects water (A) to the manifold (3), and metering pumps. electric diaphragms (10) that suck the fertilizers to the manifold (3), which are later dispersed to an irrigation system (IR). [017] More particularly, the equipment (1) by an aluminum rack (R), which houses a control board (2) on its top which is responsible for controlling the system steps through hardware, firmware, and software; an electrical panel (3) arranged on the front of the aluminum rack (R), responsible for the electrical part of the equipment.

[018] The aluminum rack (R) structure comprises a tubing (T) which is composed of a manifold (3) responsible for the movement of water (A), as well as the joining of the other tubular parts of the equipment (1), the manifold (3) contains openings and connections to the system, which orthogonally derives an elbow (C), which receives a PH probe (4), which is responsible for measuring water quality ( A), and / or the final solution, composed of water (A) and fertilizers (F) and other parameters in the equipment (1); wherein in an inferior manner the elbow (C) denotes a check valve (5) used to allow water (A) to flow in one direction of the pipe (T) and to block it in the opposite direction. The check valve (5) connects to a rotameter (6) used to measure the flow of water (A) and / or the final solution consisting of water (A) and fertilizer (F) in the pipe (T), the which is orthogonally connected to an elbow (C1), wherein said elbow (C1) connects to an EC probe (7), which measures the temperature compensated conductivity of the equipment system (1), in it is connected to the EC process controller located on the electrical panel (3). Still on the elbow (C1), it presents at its opposite end, a tube (T1) composed of a nozzle (B) responsible for the entrance of water (A) in the system, which is made through a pipe (TR) which connects to an injection pump (BJ) that picks up water from a water box (RA) and brings water (A) to the manifold (3).

[019] In short, water (A) enters the nozzle (B), which passes the EC probe (7), then the rotameter (6), then the check valve (5), then passes the flow probe. PH (4), until reaching manifold (3), which as already described above, is responsible for the movement of water (A) and / or the final solution, composed by water (A) and fertilizers (F), as well as the junction of the other tubes (T), where the manifold (3) contains openings and connections to the system, where the manifold (3) has at least four connections (8), composed of ducts (9) connected to the electric diaphragm metering pumps (10), which comprise ducts (11) connected to fertilizer filters (12), thus the diaphragm metering pumps electric (10) are responsible for sucking fertilizers (F) disposed in reservoirs (RF), and taking the fertilizers (F) to the manifold (3).

[020] The manifold (3) orthogonally presents an elbow (C2) which has a monometer (13), responsible for measuring water pressure (A) and fertilizers (F) as well as determining their velocity; In contrast to the elbow (C2), it features a solenoid valve (14) that acts and controls any system valve that is under some pressure level, as well as relieves pressure in the equipment system (1) and allowed water (A) and fertilizers (F) flow when electrical current is applied, or even the pressure itself can activate the solenoid valve (14) in reverse and create an electrical signal that is channeled to the monitoring station. Below the solenoid valve (14) is an "L" pipe (15) provided with an outlet nozzle (B1) of water (A) mixed with fertilizer (F) in an irrigation system (IR).

[021] Finally, the present innovation comprises two modes of installations, which are initially bypassed on the main irrigation line (LI), and a second moment is bypassed with the irrigation motor pump. (M1).

[020] Operation: Basically, the nozzle (B) is responsible for the ingress of water (A) into the system by means of a tubing (TR) that connects to an injection pump (BJ) that picks up water. water (A) in a water box (RA) and carries the water (A) to the manifold (3), after the water (A) passes through all the other components that make up the equipment system (1), which already described above; thus water (A) reaches the manifold (3) which has at least four connections (8), composed of ducts (9) connected to the electric diaphragm metering pumps (10), which comprise ducts (11) connected to fertilizer filters (12), thus the electric diaphragm metering pumps (10) suck fertilizers (F) from reservoirs (RF), and carry the fertilizers (F) to the manifold (3), thus water (A) and fertilizer (F) are mixed and dosed, with control by panel (P) through an operator thereafter with the monometer control (13), and the solenoid valve (14), water (A) and fertilizer (F) pass through the "L" tube (15) with an outlet nozzle (B1) from the water (A), properly controlled and metered by the control system made by the panel (P) through an operator, and are dispersed in a stable, non-oscillating irrigation (IR) system.

Claims

CLAIM

1) ARRANGEMENT APPLIED TO ELECTRICAL DIAPHRAGM DOSING PUMP EQUIPMENT FOR FERTILIZER INJECTION CONTROL IN IRRIGATION SYSTEMS refers to an equipment (1) comprising an aluminum rack (R), which houses a control box (2) ) responsible for controlling system steps through hardware, firmware, and software; an electrical panel (3) responsible for the electrical part of the equipment; wherein the aluminum rack structure (R) comprises a tubing (T) which is composed of a manifold (3) containing openings and connections (8) to the system, which orthogonally derives an elbow (C), which receives a PH probe (4), whereby lower elbow (C) denotes a check valve (5), which connects to a rotameter (6) also connected to an elbow (C1) orthogonally, wherein said elbow (C1) connects to an EC probe (7); Still on the elbow (C1), it presents at its opposite end, a tube (T1) composed of a nozzle (B) responsible for the water entry (A) in the system, which is made by means of a pipe (TR) connected to an injection pump (BJ) that captures water in a water box (RA); said manifold (3) has at least four connections (8), composed of ducts (9) connected to the electric diaphragm metering pumps (10), which comprise ducts (11) connected to fertilizer filters (12) responsible for for sucking fertilizers (F) disposed in reservoirs (RF); whereas, however, the manifold (3) orthogonally presents an elbow (C2) with a monometer (13); in contrast to the elbow (C2), it has a solenoid valve (14) which denotes just below an "L" pipe (15) provided with an outlet nozzle (B1) of water (A) mixed with the fertilizer (F) in an irrigation system (IR); It can also be bypassed on the main irrigation line (LI), and bypassed with the irrigation motor pump (M1).