SU1660607A1 - Mineral fertilizer solution mixing plant - Google Patents

Abstract

The invention relates to agriculture, in particular, to devices for the preparation of a stock solution of mineral fertilizers and its supply to a sprinkler. The purpose of the invention is to increase the efficiency of the process of dissolving the components of the fertilizer. The plant for the preparation of mineral fertilizer solutions contains a fertilizer hopper 1, a dosing chamber 3, a mixing chamber 4, a grid 5 for filtering a fertilizer solution, a float regulator 6 of the level, a feed 7 and a discharge pipe 8. Over the multistage nozzle 11 mounted rotor 38, which is made in the form of a hollow shaft. Inside the shaft there is a spring-loaded rod, and on its side surface tangential nozzles 55, 56, 57 are installed uniformly around the circumference. Nozzles 55 and 57 are installed at an angle to the vertical axis of the rotor 38. Each rus nozzles rotate circumferentially relative to the adjacent shaft. The mesh 5 for filtering the fertilizer solution in cross section has the shape of a paraboloid of rotation. Fertilizers poured into the hopper 1 are dissolved by streams of water coming out of the multistage nozzle 11 and from the tip attached to the upper end of the hollow rod. As the fertilizer dissolves, the rod begins to rise inside the hollow shaft, opening the holes of the nozzles 55. Due to the reactive forces of the water coming out of the nozzles 55, the rotor 38 begins to rotate. When the boom is further raised, the nozzle holes 56 and 57 open. Under the action of the water jets, the fertilizers dissolve, pass through the net 5 to filter the fertilizer solution, are metered and introduced into the irrigation water. 2 hp f-ly, 7 ill.

Description

The invention relates to agriculture, in particular, to devices for the preparation of a stock solution of mineral fertilizers and its supply to a sprinkler.

The purpose of the invention is to increase the efficiency of the process of dissolving the components of fertilizers.

Figure 1 shows an installation for the preparation of solutions of mineral fertilizers; figure 2 - section aa in figure 1; on fig.Z - section bb in figure 2; figure 4 - section bb In fig.Z; figure 5 - section GG on fig.Z; in fig.-b - the same, when lifting the rod; 7 - the same, with the rotation of the rotor.

A plant for preparing mineral fertilizer solutions (Fig. 1) contains a fertilizer hopper 1 mounted on base 2, a dosing chamber 3, a mixing chamber 4, a grid 5 for filtering a fertilizer solution, a float regulator 6 of the level, a supply 7 and an outlet 8 pipelines valves 9 and 10 and a multi-nozzle 11 mounted on the conical bottom of the mixing chamber 4.

In the upper part of the fertilizer hopper 1 on the vertical axis 12 there is a rotary cover 13. In the closed position, the cover 13 above the fertilizer hopper 1 is held by a spring-loaded lock 14. When the volume of the hopper 1 is filled with fertilizer cover 13, the latter is covered by moving the ring 15 of the cover 13 along the upper edge Bunker 1. This eliminates the ingress of irrigation water and sediment into the bunker for fertilizers and the preservation of the latter in the initial state for the entire irrigation period. Described

constructive execution allows for the revision of the bunker 1 for fertilizers, the condition and quality of the fertilizers and their replacement even when the irrigated position is

the sprinkler piping over the installation or during the maintenance of the machine on the technological road in the direction of the fixed support. To eliminate the formation of arches and uniform supply of fertilizers into the dosing chamber 3, the ratio of the diameter D of the bunker 1 for fertilizers to its height H does not exceed 1.0.05.

The base 2 is made of a profile angle 16 connected by welds with racks 17 made of channels. The fertilizer hopper 1 with the lower edge rests on the corner 16. This allows you to mount the fertilizer hopper 1 on the base 2 without much time and labor and ensure its stable position. The top point of the lid 13 is lower by 50 mm for the outline of the movable pipeline of the multi-support sprinkler (not shown)

The mixing chamber 4 is a cylindrical container (Figures 1 and 2) formed by the angles 18 and 19 of the cylindrical metal wall 20. A semi-circular bottom 21 with a tapered protrusion 22 in its middle part. In the semi-annular bottom 21 of the mixing chamber 4 there is a local recess with a pipe 23 on which the valve 10 of the discharge pipe 8 is screwed. The supply pipe 7 is connected to the valve 9 of the float regulator 6 of the level and with the pipelines 24 and 25. The pipe 24 is made semi-ring and placed along the wall 20. Pipeline 24

ends with a vertical slanting slice. The pipe 25 is connected by a collar 26 to the stand 27, which is connected to the conical protrusion 22 of the semi-annular bottom 21 of the mixing chamber 4 by a closed ring seam. At one hundred to 27, the adapter 28 is screwed with the multi-stage nozzle 11 with the deflector 29. A cylindrical guiding the 30 float level regulator b of the solution in the mixing chamber 4. The float 6 level regulator is connected with the valve 31 and 32 with the valve 9. By varying the length of the rod 32 it adjusts the upper position of the float regulator 6 level therefore, the volume of the mother liquor in the mixing chamber 4.

The corner 19 of the mixing chamber 4 is connected to the support ring 33 of the fertilizer hopper 1 by nuts 34, screwed onto the studs 35. A rubber gasket is placed between the nozzles of the corner 19 and the support ring 33, preventing emergency leakage of the mother liquor from the mixing chamber 4.

The dosing chamber 3 (Figs. 1-3) is made by an independent detachable unit and contains a shaped annular disk 36, which with its shoulders rests on a figure ring 33 connected to the lower part of the fertilizer hopper 1, a grid 5 for filtering the fertilizer solution, diametrically oriented brackets 37 and the rotor 38. The arms 37 are connected to the disk 39 and the annular disk 36. On the disk 39, bolts 40 fasten the hub 41 with a sliding bearing 42. In the central part of the grid 5, to filter the fertilizer solution, an annular sleeve 43 is rolled to accommodate the bearing 44. Bearings 42 and 44 are made of fluoroplastic and do not need lubrication. The surface of the net 5 for filtering the fertilizer solution in cross section has the shape of a paraboloid of rotation. On the surface of the grid 5, the technological window for maintenance of the rotor 38 is made. The rotor 38 is placed coaxially with the deflector 29 with a multistage nozzle 11 and above it. The rotor 38 is made in the form of a vertical hollow shaft of rotation. For simplicity, the manufacture of the rotor 38 and the elimination of unbalanced masses in it is made of body 45 (Fig. 5) with two threaded shaped flanges 46 and 47. The flanges 46 and 47 are screwed into the body 45 with their threaded ends. Such a constructive design of the rotor 38 allows inside its hollow part to place the hollow rod 48 and the cylindrical spring 49 compression. The lower part of the rod 48 is seamed and is a piston in the hollow part of the housing 45 of the rotor 38. The upper part of the rod 48 in the housing 45 is located in the guide 50. The rod 48 5 ends with the tip 51, which is fixed with the shaped nut 52 and the flared upper part of the rod 51 48. Tip 51 contains four inclined apertures 53 for supplying irrigation

0 water from the pipeline of the rod 48 and the hollow isti 54 of the flange 47. The nozzles 55, 56 and 57 are fixed to the housing 45 by threaded components along its outer circumference in three rusas. The nozzles 55. 56 and 57 (Fig. 3 and 4)

5 are installed one above the other with a tangential shift of the nozzles 55-57 of adjacent Russes relative to each other. The nozzles 55 and 57 are installed obliquely vertically to the axis of the waxing shaft, and the nozzles 56 are perpendicular to p0 but to whose.

The operation of the installation for the preparation of the mother liquor of mineral fertilizers is based on the intensive leaching of mineral fertilizers from the bottom of the bunker 1

5 for fertilizing with a stream of water from a multistage nozzle 11, from nozzles 55, 56, 57 of a rotating rotor 38 and holes 53 of a hollow rod 48 with simultaneous feeding of dry fertilizers into the chamber 3 of the metering station. The final dissolution of the fertilizers and the formation of the mother liquor is carried out in the mixing chamber 4. The concentration of the fertilizers discharged through the pipeline 8 to the rainwater tire is monitored by a sensor (not shown).

Installation for the preparation of the mother liquor works as follows. Before you start the installation for

The preparation of solutions of mineral fertilizers is released by releasing the fixer 14. The lid 13 is shifted around the axis 12 and poured into the bunker 1, the fertilizers and trace elements necessary for introducing into the soil. Grid 5 dl

5 filtering the fertilizer solution reliably holds them in the lower part of the hopper 1. When the fertilizer hopper 1 is filled, the cover 13 is moved to its original position. Then open the valve of the supply pipe 7. The float-level regulator 6 is located on the conical protrusion 22. From the valve 9 body, water is supplied to the pipes 24 and 25. From the total supply of 80% of water through the pipeline 25 na5 is directed to one hundred to 27, and from it, via adapter 28, into the body of the multistage nozzle 11, breaks up into small jets and is directed onto the surface of the grid 5 to filter the fertilizer solution. Making the grid 5 in the form of a paraboloid of rotation with

the apex in the bearing 44 of the rotor 38 allows the jets of water to be directed from the parabola focus aligned with the center of the deflector 29 of the multi-stage nozzle 11. Each individual stream of jets from the multi-stage nozzle 11 is directed perpendicular to the surface of the grid 5 and they efficiently wash soluble fertilizers into the mixing chamber 4 The streams of streams with fertilizer particles, reflecting on the surface of the net 5, to overturn the fertilizer solution overturn into the mixing chamber 4. The final dissolution of the fertilizers in the mixing chamber 4 o There is a second flow, yibi (20% of the initial supply), directed tangentially to the surface of the wall 20 of the chamber 4 by means of an oblique cut of the pipeline 24, forming a swirling vortex flow in it. The final dissolution of the fertilizers is carried out in an aqueous vortex flow of the mixing chamber 4. Continuously formed mother liquor of constant concentration is discharged with the valve 10 open through the discharge pipe 8 to the discharge line of the supporting pipeline of the sprinkler (not shown). The magnitude of the opening of the valve 10 regulates the rate of fertilizer applied with irrigation water. The float regulator 6 levels through the plugs 31 and 32 maintains the level of the stock solution in the mixing chamber 4. When the valve 10 is closed, the level of the stock solution in the mixing chamber 4 rises. At the same time, the float regulator 6 rises, and through rods 31 and 32 it interacts with the valve 9, shutting off the water supply to the multistage nozzle 11 and to the pipeline 24.

When the installation is operated with water jets of a short-jet multi-stage nozzle 11, there is an intensive removal of soluble fertilizers from the dosing chamber 3. This continues until then. until the fertilizers are washed off the surface of the net 5 to filter the fertilizer solution. The fertilized fertilizers in the center of the fertilizer hopper 1 above the mesh 5 for filtering the fertilizer solution in the dosing chamber 3 in the initial period of operation of the installation keep the rotor 38 in a stationary position. The remaining unused water flow from the stand 27 and the adapter 28 of the multistage nozzle 11 through the central opening of the deflector 29 is directed to the hollow part 54 of the flange 47 of the rotor 38. Due to the water flow and pressure pusher, the piston part of the rod 48 begins to perform a reciprocating movement overcoming when moving upward elastic resistance of the spring 49 and the weight of fertilizer on the tip 51, and when moving downward - the pressure of water flow.

The floor of the rod 48 in this case, with its piston part, slides along the inner wall of the housing 45, and the upper part - in the guide 50. The fertilizers placed above the rotor 38 with the tip 51 are moved onto the screen 5 from the roof to filter the fertilizer solution. Simultaneously with this stream of water jets from inclined holes 53, adhered fertilizers with brackets 37, nozzles 57, 56 and 55 and bodies 45

5 is washed off.

The pre-wetted fertilizers in the metering chamber 3 are easily released by the flow of water from the holes 53. the surface of the nozzles 55-57 and the rotor 38. When lifting

0 the rod 48 under the action of its piston part compresses the coils of the spring 49 and releases the holes of the lower shaft of the nozzles 55 in the housing 45 of the rotor 38, into which water is supplied under pressure, are released. Due to the reactive effect of the jet of water streams from tangentially directed nozzles 55, the rotor 38 starts to rotate counterclockwise. The water jet from the nozzles 55 blurs the base of the fertilizer arch from the surface.

0 mesh 5. The simultaneous intersecting action of the jets of water flows from the holes 53 of the tip 51, from the nozzles 55 of the rotor 38 and fine jets from the deflector 29 of the short-jet nozzle 11 leads to

5 intensive washing out of fertilizers and washing them from the surface of the grid 5 to filter the fertilizer solution, freeing their openings from sludge for active access of the streams of jets from the multi-stage nozzle

0 11.

Fertilizer ruptured by nozzles 55 reduces the load on tip 51, and under the pressure of the floor water, rod 48 begins to move upwards. Water streams from

The 5 holes 53 of the boom 48 are used to wash down fertilizers with the nozzles 55.56 and 57 of the rotor 38. When the rotor 38 is released due to the reactive force of the jets from the nozzles 55 and 56, the fertilizers are washed away from the surface of the net 5 for

0 fixing fertilizer solution. The nozzles 56 erode the fertilizer vault on the peripheral part of the fertilizer hopper 1, and the nozzles 55 erase the latter from the surface of the net 5. At the position of the movable head

5 48, shown in Fig. 7, the nozzles 57, when the rotor 38 rotates, perform the role of a tedder and displace fertilizer from the brackets 37 and the hub 41. Only when the arch reaches a height of more than double the length of the rod 48, the inclined nozzles 57 of the upper the rotor 38. In this case, the vault and the entire mass of fertilizers along the walls of the hopper 1 completely break down into the dosing chamber 3 under the weight of the fertilizers, the tip 51 with the force of compressed springs overcomes the force developed by the piston part of the rod 48 in the hollow part of the rotor 38. Later The process of fertilizer batch feeding is repeated in a similar way.

Claims (3)

Claim 1. Installation for the preparation of solutions of mineral fertilizers, containing a fertilizer hopper, a dosing chamber, a mixing chamber, a grid for filtering a fertilizer solution, a float level controller, supply and discharge piping and a multi-stage nozzle installed on the conical bottom of the mixing chamber characterized in that, in order to increase the efficiency of the process of dissolving the components of the fertilizers, it is equipped with a reactive rotor, which is mounted to rotate over the multi-stage coaxially with the nozzle and chatoy made in the form of a vertical hollow shaft, inside which there is a spring-loaded rod, and on the lateral surface of the rotor tangential nozzles are uniformly circumferentially fixed, and the nozzles are set at an angle to the vertical axis of the shaft and each rus nozzles are rotated relative to each other. 2. Installation pop, 1, characterized in that the mesh for filtering the fertilizer solution in the cross section has the form of a pair & rotation of rotation and technological windows are made in it. 0 3. Installation pop. 1, characterized in that the ratio of the diameter of the bunker to its height does not exceed 0.05. 21 Aa 37 39 37 f 0 one Yr