ES2228192B1 - ADJUSTABLE PAYER FOR ROTATION OF VENTURI TUBES - Google Patents

Abstract

The main objective of the "Adjustable Venturi Tube Rotator" is to be able to regulate the inlet flow inside the venturi tube, overcoming the limitation of not being able to regulate the amount of water and its velocity as it passes through the suction point of the venturi tube Thanks to the piece called "rotor" (C) containing eight venturi tubes with different diameters, the invention allows the internal diameter of the water passage to be adapted to the hydraulic characteristics of the installation. The invention is characterized by being able to perform the regulation by rotating the rotor from the outside, without having to disassemble the apparatus. You can inject, with easy handling, the dose that is required at any time, regardless of pressure and flow, being very useful for any type of agricultural or livestock installation.

Description

Adjustable tube rotation fertilizer venturi

Technical sector

The invention is intended primarily for the sector of the localized irrigation, being used as a fertilizer injector or other liquids

Background of the invention

Prior to this invention, in the agriculture, livestock, etc., there are devices that work by venturi effect with a single pitch diameter. These appliances are exposed to changes in pressure and flow, if this happens, the initial dosage values are lost or the device Stop working

There is another type of venturi injector that has four interchangeable nozzles with four different diameters. To adapt this to the needs of the irrigation facility, it is it is necessary to disassemble the device from the installation and then disassemble the device itself to remove the nozzles from its inside. Once extracted, another game is mounted without having the certainty that the game chosen is the right one. If they ride and not they are appropriate, the entire operation has to be repeated again, until you hit the game that suits. This venturi injector only It allows a total of four adaptation possibilities.

The invention I present is endowed with a system that allows to adapt to pressure alterations to maintain the appropriate dose at all times without needing disassemble the device. This is achieved by rotating the rotor that It has eight venturi tubes with different diameters up to select the venturi tube that suits the pressure and flow existing. The main objective is to regulate the flow rate of water inside the device, without disassembling it and increasing the adaptation possibilities

Explanation of the invention.

"Adjustable tube rotation fertilizer venturi ". This invention is designed to adapt the dose of payment to the changes of flow and pressure that may suffer the facilities where its use is required. The objective The main thing is to be able to regulate the input flow into the device overcoming the limitation of not being able to regulate the amount of water and its speed passing through the suction point of the venturi tube. To the contain eight venturi tubes with different diameters, the invention, allows to adapt the internal diameter of the water passage to the hydraulic characteristics of the installation.

The invention consists of three pieces and three Accessories: The first piece called "rotor" is the piece which enables the regulation of the device, and is characterized by house eight venturi tubes of different flow rates. its regulation is carried out from outside the device by manual operation by means of a handle, or with a gear in Case of being automated. The handle and gear are accessories They are mounted on the rotor shaft and are interchangeable. The second piece is called "rotor housing". This piece has a cylindrical emptying that houses the rotor. In this piece you will find one of the output holes of the rotor shaft and the manifold of water inlet to the chamber where the rotor is located. In its bottom has the entrance hole of the fertilizer, which arrives to the chamber with the help of a flowmeter, which is another Attachable accessory to the invention. The third piece is called "camera cover". In this piece is the collector of output and the other output hole of the rotor shaft. In these two last pieces that make up the camera, are located in their housings, seals and o-rings necessary for the tightness and correct operation of the invention. He operation of the "Adjustable fertilizer by tube rotation venturi ", as the name implies, is to select one of the tubes rotor venturi, rotating it until the tube is aligned selected between the input and output collectors, forming thus a single tube that will allow its connection to the installation by Where the water will pass Through the input manifold you will reach the venturi tube of the rotor where the known effect will occur venturi, creating a vacuum by suction in the chamber that houses the rotor. As a consequence of this, through the flowmeter duct, the subscription enters the chamber. Through the rotor groove, it channels the fertilizer to the suction point to be injected into the  outlet manifold to the irrigation facility.

Brief description of the drawings

On page 10 is Fig. 1. In it you can see the exploded view of the "Adjustable fertilizer by venturi tube rotation ". From right to left you will find the piece called "Rotor Housing" (B). The next piece is called "Rotor" (C). The last piece is named of "Camera Cover". Below are the accessories. Also, from right to left the flow meter (D) to measure the fertilizer flow. Next to it is the handle (E) to manually regulate the water inlet flow, and by Finally, the gear that will be used when the regulation is perform automatically.

On page 11 Fig. 2 there is a view of the "Venturi adjustable tube fertilizer spreader" to which a sectional cut has been made to see clearly the location of the rotor (C) in the chamber and the alignment of the nozzles of the venturi tubes, between the manifolds (8 and 9). At drawing you can clearly see how the nozzle is aligned outlet (2) of the venturi tube of the rotor with the outlet manifold (9). Although it is not seen in the drawing, the same happens with the rotor inlet nozzle and inlet manifold (8). Between the manifolds (8 and 9) and the rotor there is an o-ring (6) for prevent the pressure of the tube (2) from passing to the chamber (21-free space between the perimeter of the rotor and the inside diameter of rotor housing). Between the nozzles of the rotor is the groove (3) where the fertilizer from the chamber to the nozzles where the venturi effect

The flow meter (D) is equipped with a valve non-return (19), this flowmeter will drive the fertilizer to the camera at the same time that will be used to measure the flow rate of fertilizer. The seal of the rotor shaft (4) is achieved by two seals (5) housed inside the chamber: one in the lid (A) and another in the rotor housing (B). Camera closure with the cover (A) it is sealed, by means of the seals (5) of the shaft (4) and a tonic seal (7) that is attached to a channel that has the rotor housing (B) for this purpose.

On page 12 Fig. 3 there is a view of the "Adjustable fertilizer by rotation of venturi tubes", which in This case has been mounted with the accessories for manual function, in which you can see the lid (A): through the center of the lid the rotor shaft (4) comes out, to which one of the ends is coupled of the handle (E), the other end of the handle is attached to the other end of the shaft (4), which goes outside through the rotor housing (B). These pieces are mounted with 9 screws (23) that will be flush with the cover inside your housing (12) closing the rotor in the inner chamber of the rotor housing (B). Water enters through the end of the tube input manifold (8) and at the opposite end the output of the mixture with the fixed dose, which is absorbed by another accessory (D) called flowmeter. Fixing to the installation it will be done by means of two male thread sockets (10 and 11) that are located at the ends of the device.

On page 13 Fig. 4 we can see a cut longitudinal section that cuts the invention in half. This draw, has been used to develop the description of realization, in he can see all the pieces, seals, gaskets and accessories that form the "Rotary adjustable fertilizer venturi tubes ". The relation of pieces and their function is the next: the first piece is the "camera cover" (A) and its most significant function is to support the rotor shaft (4) and the fastening to the installation by means of the thread (10) of the collector exit (9). The second piece is "the rotor housing" (B). In this piece is the chamber (21) and the other shaft hole (4) of the rotor. This piece has a fixing thread (11) for its installation installation in the inlet manifold (8) and the hole (15) with the thread of the flow meter where the fertilizer or liquid. In it is the third piece that has been called "rotor" (C). This piece is the most characteristic of the invention, in it are the venturi tubes that form the nozzles (1 and 2) separated by a channel (3) where it will be absorbed the fertilizer or liquid. The fourth piece is the accessory called flowmeter (D). It will be used to measure the amount of fertilizer or liquid that is injected.

Description of realization

This fertilizer will be made of plastic material and resistant to different types of fertilizer and chemicals employees in agriculture.

On page 13 there is a representation of the body sectioning of the "Adjustable fertilizer by tube rotation venturi ". The first piece called" camera cover " (A), is crossed by a central hole that exits the shaft of the rotor (4). The shaft exit hole has a recess that it surrounds it, in which the retainer (5) is housed. The outlet manifold (9) it has a hole located in its narrowest conical part, around it a slot has been made where it will fit an o-ring (6) that will prevent pressure leaks, between the rotor (C) and the cover (A) towards the chamber (21). The lid closure (A) is made by screws, through nine holes (13), distributed by its perimeter. A seat (12) has been drilled to the screws, in this way the heads of these do not protrude from the cover (A). The outside of the outlet manifold tube (9) is equipped with a male thread (10) used to fix the device to the irrigation installation.

The second piece called "rotor" (C) is a cylindrical piece in whose interior, and arranged around its axis, there are eight conical holes that form the tubes rotor venturi. The rotor has had a groove or channel (3) that deepens to section, in its narrowest part, the venturi tubes of the rotor dividing them in two, and forming the nozzles (1 and 2), differentiating, the input (1) and those of output (2). A shaft (4) is born from the two flat faces of the rotor, which presents at its ends a square termination, in order to be able to crimp the lever or gear.

The third piece is called "accommodation of rotor "(B) in it is the rotor chamber (21) where is the second exit hole of the rotor shaft and its retainer (5). This piece has a housing for the O-ring (7) just between the holes for the thymes and the chamber (21), which will prevent that between the cover (A) and this piece (B) leaks may appear towards The outside of the device. The input manifold (8) has a hole located in its narrowest conical part. Around this a groove has been made where an O-ring will be fitted (6) which will prevent pressure leaks between the rotor (C) and the Housing of the rotor (B) towards the chamber. Like the camera cover has nine holes (13) distributed around its perimeter. The nuts are embedded in the holes (14) so that the nuts do not turn when  tightened the screws and also do not protrude from the piece. He outside the inlet manifold tube (8) is provided with a thread male (11) used to fix the device to the installation of irrigation. Pressurized water will enter this line (8). The subscription or liquid, will enter the chamber through a hole (15) from the outside of the device The fertilizer flow will be measured by means of an accessory called flowmeter (D). This flow meter will be provided with a cavity (20) where a non-return valve (19) with ball will go (18). The flowmeter will be fixed to the invention by means of a male thread (17) that will be the same step as the female thread (16) which has the rotor housing (B).

Claims (1)

1. The Venturi tube adjustable rotation fertilizer has the regular function and adapts the internal diameter of the water passage to the hydraulic characteristics of the installation, and is characterized by changing the venturi tube, manually rotating the rotor (C) from outside the appliance, using a handle (E) without dismantling anything that could interrupt the irrigation and fertilizer process. The Venturi tube adjustable rotator by having moving parts has the possibility of being able to regulate the flow passage from the outside automatically by means of a hydraulic apparatus, therefore the invention is accompanied by a gear (F) as a characteristic accessory for its automation. The invention is characterized in that it consists of two cylindrical pieces (A and B) that configure an internal space where the rotor (C) rotates. The rotor is a cylindrical piece that is characterized by having eight conical holes, each of these holes configures a venturi tube (1 and 2) of different diameter. These tubes are arranged around the rotor shaft (4). The rotor shaft (4) has a square termination at its ends, in order to be able to crimp the handle (E) or gear (F) and rotate the rotor (C) from outside. The rotor features a groove (3) that deepens from the perimeter of the latter, until it reaches the suction point of all venturi tubes. This slot (3) has the necessary separation between the tubes to create the venturi effect and suck the fertilizer or liquid that enters the chamber (21). The smaller diameters split from the groove forming the cones of the venturi tubes to the faces of the rotor. The rotor has two flat faces where the larger diameters of the venturi tubes (1 and 2) are located. These diameters are the same as the diameters of the manifolds (8 and 9) of the chamber cover (A) and the rotor housing (B). These manifolds are characterized by having an O-ring (6) that surrounds the hole of the manifolds (8 and 9). These joints (6) are pressed against the faces of the rotor (C) and the manifolds (8 and 9) preventing pressure leaks between the faces of the rotor and the manifolds in the chamber. The dimensions of the nozzles comprise from 2 mm to 9 mm in diameter, these measures may be greater or smaller depending on the size of the apparatus.