RU2634275C1 - Plant for preparing salt solution for purifying drinking water at water intakes - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: plant comprises a rotating drum and a body. The drum is mounted from sections made of six, eight, ten, twelve, etc. even number of equilateral triangles connected to each other by two lateral sides. The sections are connected to each other by free third sides of triangles to form a screw drum, three, four, five, five, six and more broken right and left screw lines and provided with internal three, four, five, six and more screw grooves facing each other with the same pitch. There are three and more tension springs with flat section of turns mounted inside the drum and equipped with a device for changing the pitch of the turns by its stretching or compression. The drum is provided with a loading device in the form of a bushing, which inner surface is fixed at an angle of at α least three screw inserts of rectangular shape curved in width and length by known methods.

EFFECT: simplified manufacture, increased efficiency and expanded technological capabilities of the plant.

15 dwg

Description

The invention relates to devices for water purification, namely for the purification of drinking water at intakes.

A device is known for mechanical water purification (USSR AS No. 1318666, class E03F 5/14, 1987), comprising a chamber with a grill and a blade wheel, brush and screw installed in it, the shafts of the latter of which are interconnected, as well as a perforated drum and additional brushes and auger, while the impeller is mounted inside the perforated drum eccentrically relative to its axis of rotation and kinematically connected with the shaft of the additional brush and the shaft of the perforated drum, with additional brushes and auger located inside the morning of the perforated drum, the shaft of which is kinematically connected with the shaft of the brush located outside the perforated drum.

A disadvantage of the known device is the complexity of manufacture and operation, insufficient productivity, as well as limited technological capabilities.

Closest to the proposed invention is a device for mechanical water purification (AS USSR No. 1481348, class E03F 5/14, 1987), comprising a housing, a regulator shield, a rotary perforated drum, its cleaning mechanism and the impeller, mounted on the floats and kinematically connected by a telescopic driveshaft with a drum and a cleaning mechanism, which is made in the form of a collision tray and a conveyor belt with pins located under the collision tray having longitudinal slots for accommodating the pins and comb whose elements are located in the corrugations of the drum.

A disadvantage of the known device is the complexity of manufacture and operation, insufficient productivity, as well as limited technological capabilities.

The technical result of the task is to simplify manufacturing, increase productivity and expand technological capabilities.

The technical result is achieved by the fact that in the installation for the preparation of brine for the purification of drinking water at intakes containing a rotating drum and a housing, the drum is mounted from sections made of six, eight, ten, twelve, etc. an even number of equilateral triangles connected by two lateral sides, while the sections are connected to each other by the free third sides of the triangles with the formation of a screw drum, along the perimeter of which there are three, four, five, six or more broken right and left screw directed towards each other lines and equipped with internal three, four, five, six or more screw grooves directed towards each other with the same pitch, and three and more are mounted inside the drum e tension springs with a flat section of the coils, which are equipped with a device for changing the pitch of the coils by stretching or compressing it, and the drum is equipped with a loading device in the form of a sleeve, at least three rectangular screw inserts curved in width and length are attached at an angle α known methods.

According to the patent literature not found a technical solution similar to the claimed, which allows to judge about the inventive step of the proposed design of the installation of the preparation of brine for the purification of drinking water at intakes.

The novelty is due to the fact that the elements from which the drum is assembled are mounted at certain angles to each other, so the intensity of mixing the flows of water and salt increases, since these elements, working as shelves, capture their portions and direct them towards each other, violating thus, the stationarity of their movement, which intensifies the dissolution of salt granules in water and increases the rate of production of saline, increases productivity, expands technological capabilities and simplifies manufacturing.

The novelty of the invention lies in the fact that, since the frequency of movement of salt granules and water flows in the proposed structures is determined not only by the frequency of rotation of the drum, but also by the number of flat elements around the perimeter of the drum, such a structural design of the surface of the drum by increasing the number of flat elements in each section along the perimeter increases for each revolution of the drum the frequency of collisions of salt granules and water flows between each other and with the walls of the drum, increases productivity, expands technological capabilities, intensifies the dissolution of salt granules in water and increases the rate of production of saline.

The novelty is seen in the fact that the area and shape of the cross section of the drum changes in each of its cross sections, which provides not only an intensification of the mixing process, but also compresses and expands the flows of salt granules and water, increases the frequency and energy intensity of the interaction of salt granules and water flows with each other and with the walls of the drum, increases productivity, expands technological capabilities, intensifies the dissolution of salt granules in water and increases the rate of production of saline.

The novelty is also due to the fact that not only the triangles from which the drum sections are assembled, but the sections themselves are mounted at certain angles to each other with the formation of broken helical lines, which increases the miscibility, energy intensity and changes the frequency of interaction of salt and water granules with each other and with the walls of the drum, which intensifies the dissolution of salt granules in water and increases the rate of production of saline, which means it increases productivity and expands technological capabilities.

The novelty is due to the fact that the drum is equipped with three, four, five, six or more helical broken lines of equal pitch, directed towards each other along the perimeter of the drum, and, accordingly, three, four, five, six or more helical grooves inside the drum, directed also towards each other, which ensures the creation of flows of salt and water granules directed towards each other with maximum energy intensity of collisions with each other and with the walls of the drum at different angles, increases the frequency of their interaction, ovyshaet performance expands technological possibilities intensifies dissolving salt in water the granules and increases the rate of production of brine.

The novelty of the invention lies in the fact that due to the design features of the loading device, not only the uninterrupted flow of salt granules into the drum is ensured, productivity is increased, technological capabilities are expanded, but their uniform flow inside the drum is also ensured.

The novelty also lies in the fact that the screw inserts are attached to the inner surface of the loading device in the form of a sleeve at an angle α and are folded in width and length, which expands the technological capabilities.

The novelty also lies in the fact that three or more tension springs with a flat section of coils are mounted inside the drum, which are equipped with a device for changing the pitch of the coils by stretching or compressing it, which increases mixing, the rate of dissolution of salt in water, and expands technological capabilities.

The invention is illustrated by drawings, where in FIG. 1 shows the installation of the preparation of brine for the purification of drinking water at intakes - front view; in FIG. 2 is a section AA in FIG. one; in FIG. 3 - the drum is mounted from sections made of six equilateral triangles, front view; in FIG. 4 is a section BB in FIG. 3; in FIG. 5 is a cross-section BB in FIG. 3; in FIG. 6 is a section GG in FIG. 3; in FIG. 7 - the drum is mounted from sections made of eight equilateral triangles, front view; in FIG. 8 is a section DD in FIG. 7; in FIG. 9 - the drum is mounted from sections made of ten equilateral triangles, front view; in FIG. 10 is a cross-section EE in FIG. 9; in FIG. 11 - the drum is mounted from sections made of twenty-four equilateral triangles, front view; in FIG. 12 is a section FJ in FIG. 9; in FIG. 13 - sleeve loading device; FIG. 14 is a cross-section ZZ in FIG. 13, FIG. 15 - insert in the form of a curved plate.

The installation for the preparation of saline solution for the purification of drinking water at the intakes (Fig. 1, Fig. 2) consists of a drum 1, loading 2 and unloading 3 devices and a drive (not shown in the drawings). The drum 1 is equipped with bushings 4 and 5 with the possibility of rotation in the bearing bearings 6 and 7. The boot 4 of the boot device 2 includes the sleeve 4 of the drum loading device 1. The loading device 2, the bearing bearings 6 and 7 with the drum 1 mounted in them, are mounted on the housing 8. The unit for the preparation of saline solution for the purification of drinking water at the intakes is equipped with a pipeline 9. Inside the drum 1, three or more tension springs 10 with a flat section of coils are mounted, which are equipped with a device for changing the pitch of the spring coils by their extension or compression.

Drum 1 (Fig. 3, Fig. 4, Fig. 5) is mounted from sections 11 assembled from six equilateral triangles 12 connected by faces 13 and 14, with sections connected to the drum 1 along the free faces 15 of equilateral triangles 12. As a result connecting sections to each other, a helical multi-start surface is formed with pronounced multi-start continuous broken helical lines directed towards each other. In FIG. 3 thickened lines show one of the three right broken helical lines 16-17-18-19-20-20-22-22 in increments of S ₁ and one of the three left broken helical lines in the opposite direction 23-24-20-25-26-17- 27 in increments also S ₁ . Drum 1 is characterized in that the area of its passage section along the length varies many times, for example, from a hexagon (Fig. 4) to a triangle (Fig. 5) and again to a hexagon (Fig. 6).

In FIG. 7 and FIG. 8 shows a drum 1, sections of which are assembled from eight equal equilateral triangles 28 (in Fig. 7, a triangle 28 is shown by a double line) with the formation of four right and four left broken helical lines with equal pitch along the perimeter of the drum. In FIG. 7 shows the thickened lines 29-30-31-32-33-34 one of the four right broken helical lines in increments of S ₃ and 35-36-32-37-38-39 one of the four left broken helical lines. Step S _{2 of} these lines is the same. Such a drum 1 is characterized in that the area of its passage section along the length varies many times, for example, from a quadrangle to an octagon and again to a hexagon (Fig. 8).

In FIG. 9 and FIG. 10 shows a drum 1, the sections of which are assembled from ten equilateral triangles 40 (shown in FIG. 9 by a double line) of the same area, connected together by two lateral sides 41 and 42, while the sections are interconnected by third, free sides 43 triangles 40.

The vertices of the triangles form around the perimeter of the drum 1 five right and five left broken helical lines (Fig. 9, Fig. 10) with the same step S ₃ . One of the five left broken helix lines with step S _{3 is} shown in FIG. 9 thickened line 44-45-46-47-48-49-50-51-52. One of the five right broken helix lines, also with a step S _{3, is} shown in FIG. 9 thickened line 53-51-54-55-56-57-46-58-59.

In FIG. 11 and FIG. 12 shows a drum, sections of which are assembled from 24 equal equilateral triangles 60 (shown in Fig. 11 by double lines) with the formation of twelve right and left broken helical lines along the perimeter of the drum directed towards each other. One of the twelve right-hand broken helical lines in increments of S _{4 is} shown in FIG. 11 with a thickened line 61-62-63-64-65-66-67-68-69-70-71-72. One of the 12 left broken helix lines with step S _{4 is} shown in FIG. 11 thickened line 73-74-75-76-77-78-66-79-80-81-82-83.

Since the entrance to the drum 1 has the shape of a polygon (Fig. 4, Fig. 8, Fig. 10, Fig. 12) and has faces at the entrance to the end hole of the drum, the slope of which (through one face) is opposite to the direction of movement of the salt granules, for each revolution of the drum, there is a return by these opposed faces of portions of salt back to the loading device 2, i.e. against moving streams of salt from the device for loading 2 into the drum 1. As a result, the uninterrupted supply, dosage and reliability of the supply of salt granules into the drum 2 is not ensured, which reduces productivity, reliability and limits technical capabilities. Therefore, after the loading device 2 (FIG. 1) to the end of the drum 1, the flange 84 of FIG. 13, a sleeve 4 of a loading device is attached to the drum 1, to the inner surface of which are attached at an angle α at least three rectangular screw inserts 85, curved in width and length by known methods

The installation of the preparation of brine for the purification of drinking water at the intakes works as follows. Salt granules are loaded into the drum 1 by means of a loading device 2 in a continuous stream. When the drum 1 rotates, the screw inserts 85 (Fig. 1) capture portions of salt granules from the loading device 2 due to their rotation together with the sleeve 4 and due to their curvature in width and length, as well as their location at an angle α and to the axis of rotation of the drum 1 salt granules are transported inside the drum 1, thereby ensuring uninterrupted loading and continuous operation. Through the pipe 9, dissolution water is supplied in a continuous stream to the drum 1. Thanks to the elements in the form of equilateral triangles, from which the drum 1 is assembled, mounted at some angles to each other and to the axis of symmetry of the rotation of the drum 1, the intensity of mixing the flows of water and salt increases, since these elements, working like shelves capture their portions and direct them towards each other, thus violating the stationarity of their movement, which intensifies the dissolution of salt granules in water and increases the rate of production of saline.

Thus, when the drum 1 rotates, flat elements - equilateral triangles mounted around the drum perimeter differently inclined to the axis of rotation of the drum and to each other, working as buckets (shelves) capture different portions of salt and water, raise them in the direction of rotation of the drum slightly higher angle of repose, and then send these portions in directions perpendicular to these shelves (buckets), at a certain angle not only to the axis of rotation of the drum, but also towards other mass flows of granules of salt and water, moving inside the drum at different angles and at different speeds. The length of the motion path (amplitude) of the flows of salt and water granules largely depends on the diameter of the drum, on the angles of inclination of the flat elements to each other and to the axis of rotation. The frequency of movement and collisions of the masses of the flows of salt and water is determined not only by the frequency of rotation of the drum, but also by the number of flat elements around the perimeter of the drum. This is facilitated by tensile springs with a flat coil section. Therefore, in the proposed design of the installation of the preparation of brine for the purification of drinking water at the intakes, the frequency characteristics are increased tenfold, and technological capabilities are expanded. Since the shape and dimensions of the cross section having the shape of a polygon change many times along the length of the drum 1 from loading to unloading, multiple periodic compression of the salt and water flows is ensured, which increases the mixing intensity, the energy intensity of the collisions, expands technological capabilities, and increases productivity.

The finished saline solution through the bushings 5 is discharged into the unloading device 3.

Technical and economic advantages arise due to an increase in the frequency of interaction of salt granules and water not only with each other, but also with the walls of the drum, which increases mixing intensity, increases the energy intensity of the interaction of salt granules and water, increases the dissolution productivity and extends technological capabilities.

Claims (1)

Installation for the preparation of brine for the purification of drinking water at intakes, containing a rotating drum and a housing, characterized in that the drum is mounted from sections made of six, eight, ten, twelve, etc. an even number of equilateral triangles connected by two lateral sides, while the sections are connected to each other by the free third sides of the triangles with the formation of a screw drum, along the perimeter of which there are three, four, five, six or more broken right and left screw directed towards each other lines and equipped with internal three, four, five, six or more screw grooves directed towards each other with the same pitch, and three and more are mounted inside the drum e tension springs with a flat section of the coils, which are equipped with a device for changing the pitch of the coils by stretching or compressing it, and the drum is equipped with a loading device in the form of a sleeve, on the inner surface of which at least three rectangular screw inserts are curved in width and angled length by known methods.

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