RU2381072C2 - Method for liquid purification from ferromagnetic particles and installation for its realisation - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: group of inventions may be used for purification of lubricant-cooling liquids (LCL) and recovery of lubricant oils quality by content of ferromagnetic admixtures. Processed liquid is supplied to reservoir along supplying nozzle in the form of rectangular chute along channels produced by partitions installed at identical distance from each other between rotary cylindrical magnetic disks. Ferromagnetic particles settled on magnetic disks are removed by accessory for cleaning, which is arranged in the form of inclined comb from non-magnetic material with ledges and chutes with scrapers. Water jet is used to flush ferromagnetic sludge from comb chutes. Mixture of water and sludge is sent into the field of centrifugal forces. Water and solid phases are separated. Water is sent for reuse, and ferromagnetic sludge with remaining water is sent serially to drier and container with further remelt of ferromagnetic sludge.

EFFECT: improved efficiency and extent of LCL purification, increased efficiency of installation operation.

2 cl, 1 tbl, 5 dwg

Description

The invention relates to oil refining, petrochemicals and metalworking and can be used to clean cutting fluids, coolants, restore the quality of lubricating oils by the content of ferromagnetic impurities, other technical fluids and oils used as coolants when turning, milling, drilling, blade processing grinding, honing, superfinishing and other technological operations and metal processing processes, which are characterized by high static loads, high temperatures tours, the influence of the material being processed in the cutting tool, forging and rolling equipment.

A known method of purifying a liquid from ferromagnetic particles and a device for its implementation [1].

A method for purifying liquids from ferromagnetic particles consists in feeding the liquid to be cleaned into a container, passing it through a magnetic system, cleaning the magnetic rods and removing the purified liquid from the container.

The installation for implementing this method comprises a container for the liquid to be cleaned with an inlet and outlet pipe, a magnetic system in the form of a drive endless chain conveyor located inside the vessel with magnetic rods attached to it, and a device for cleaning the rods.

The disadvantages of this method and installation are low performance and reliability during operation, because during operation of the installation, uneven sagging or pulling of various chain zigzags occurs, which is explained by different forces transmitted from the drive to different zigzags (depending on their distance from the drive sprocket). For this reason, the circuit breaks, breaks the magnetic rods, and other malfunctions, leading to a decrease in the coolant cleaning wall, inconvenience, and reduced operation efficiency of the installation.

A known method of purifying a liquid from ferromagnetic particles and installation for its implementation, developed (company "Montanus" (Germany)) [2].

A method of purifying a liquid from ferromagnetic particles consists in feeding the liquid to be cleaned into a container, passing it through a magnetic system, cleaning the magnetic rods and removing the purified liquid from the container.

The installation for implementing this method comprises a container for the liquid to be cleaned with inlet and outlet pipes, a magnetic system in the form of a drive endless chain conveyor located inside the tank with magnetic rods attached to it and a device for cleaning the rods.

The disadvantages of this method and installation are the low degree of purification of the coolant, the inconvenience and low efficiency of operation of the installation.

The disadvantages are due to: firstly, the possibility of a one-time passage of liquid magnetic rods, which significantly reduces the degree of purification of the coolant; secondly, the impossibility of removing mechanical impurities from the bottom of the tank during operation of the installation, which explains the inconvenience of using the latter due to the need for frequent shutdown during operation and removal of mechanical impurities from the bottom of the tank, which, in turn, significantly reduces the efficiency of the process cleaning up.

The closest in technical essence and the achieved effect to the invention is a method for cleaning liquids from ferromagnetic particles [3], selected as a prototype.

A method of purifying a liquid from ferromagnetic particles involves supplying a liquid to be cleaned into a container, passing it through a magnetic system with a moving endless chain conveyor with magnetic rods fixed to it, cleaning the magnetic rods from sludge and withdrawing the purified liquid from the reservoir. This method of cleaning differs in that after supplying the liquid to be cleaned into the tank, it is directed along the inclined base of the tank, passed through a magnetic system with an endless chain conveyor moving counterclockwise towards the inlet pipe with magnetic rods fixed to it. Next, they are divided into main and auxiliary flows, which are removed from the tank through the corresponding nozzles, while regulating the liquid flow of the main stream by changing the liquid flow of the auxiliary stream, and the auxiliary liquid stream is re-directed to the liquid supply system for cleaning.

The closest in technical essence and the achieved effect to the invention is the installation for cleaning liquids from ferromagnetic particles [4], selected as a prototype.

The installation comprises a container for the liquid to be cleaned with inlet and outlet pipes, a magnetic system with sludge-collecting elements, a device for cleaning the sludge-collecting elements, the base of the tank for the liquid to be cleaned is made of a cylindrical shape. A magnetic system with sludge-collecting elements is a hollow cylindrical drum with rectangular windows, inside which are mounted rectangular magnetic blocks and a cam movement mechanism, and on the outside there is a squeezing roller with a spring, magnetic blocks are made of upper and lower magnetic elements, which are alternating flat magnets and non-magnetic gaskets, the upper magnetic elements being hermetically mounted in windows on the surface of a hollow cylindrical drum and positioned wife in the same plane with the corresponding lower magnetic elements mounted on a ferromagnetic base with the possibility of coaxial movement of the lower magnetic elements relative to the upper by means of a cam movement mechanism.

The disadvantages of this installation are the low productivity and the degree of purification of the liquid from ferromagnetic particles due to the relatively small area of the working surface of the magnetic cylindrical drum and the relatively large distance between the base of the container for the liquid being cleaned and the surface of the magnetic drum.

The invention solves the problem of increasing the productivity and the degree of purification of cutting fluids, lubricating oils and other technical fluids from ferromagnetic particles.

The problem is achieved by a method of cleaning liquid from ferromagnetic particles, including the supply of the liquid to be cleaned through an inclined inlet pipe made in the form of a rectangular gutter with a thin layer along the channels formed by partitions installed at the same distance from each other between the cylindrical magnetic disks and along the outer cylindrical surface of the magnetic disks rotating clockwise relative to the direction of movement of the liquid being cleaned, removing ferromagnetic particles from magnetic disks with a device for cleaning sludge-collecting elements, made in the form of an inclined comb made of non-magnetic material with protrusions and grooves with scrapers, washing off a ferromagnetic slurry from a comb grooves with a water jet, while a water stream is directed to the lower part of the groove towards the side of the comb, the water mixture is directed and sludge in the field of centrifugal forces, in which the mixture acquires intensive rotational motion, the aqueous and solid phases are separated, after which the water is sent for reuse, and the ferromagnetic sludge the remaining water is sent sequentially in the desiccant container and subsequent remelting of the ferromagnetic sludge.

The installation for implementing the method comprises a container for the liquid to be cleaned, the base of which is made of a cylindrical shape, with inlet and outlet pipes, a magnetic system with sludge-collecting elements, a device for cleaning sludge-collecting elements, in which the inlet and outlet pipes are made in the form of a rectangular gutter of non-magnetic material, the inlet pipe is equipped with partitions of non-magnetic material installed at the same distance from each other between the sludge collecting elements, in filled in the form of cylindrical magnetic disks of the same size, placed on the shaft with a flat, between which sleeves are made of non-magnetic material, while the holes in the magnetic disks and bushings are made corresponding to the shape of the shaft with a flat, the device for cleaning sludge-collecting elements is made in the form of an inclined combs of non-magnetic material with protrusions and gutters with scrapers, the length of the combs of the combs is equal to the radius of the cylindrical magnetic disks, and the width of the combs of the combs is less than the length of the sleeve, in all troughs in the upper part there are tubes made of non-magnetic material in the direction of the comb inclination, while the outlet pipe of the unit is connected through a pump to a hydrocyclone, the discharge pipe of which is connected in series with a desiccant and a container for collecting the ferromagnetic sludge prepared for remelting, and the drain pipe of the hydrocyclone is connected to a water supply line to remove ferromagnetic sludge from the gutters. These distinctive features are essential for solving the problem of the invention.

For the method:

1. The liquid being cleaned is directed through an inlet pipe made in the form of a rectangular gutter with a thin layer along the channels formed by partitions installed at the same distance from each other between cylindrical magnetic disks. This distinguishing feature ensures that the liquid being cleaned is supplied with a thin layer and passes along both the outer surface of the magnetic disks and along the side surfaces, which significantly increases the performance and degree of purification of lubricating oils, cutting fluids, and other liquids and increasing the operational efficiency of the installation, depending on tasks to be solved.

2. Pass the liquid to be cleaned through the magnetic system along the outer cylindrical surface of the magnetic disks and through the channels between the disks rotating clockwise relative to the direction of movement of the liquid being cleaned. Clockwise rotation of the disks ensures maximum contact (in time) of the liquid being cleaned with the surface of the magnetic disks and, accordingly, the productivity and degree of purification of lubricating oils, cutting lubricants and other liquids and increasing the operational efficiency of the installation depending on the tasks being solved, respectively.

3. Remove the ferromagnetic particles from the magnetic disks with a device for cleaning the sludge collection elements, made in the form of an inclined comb made of non-magnetic material with protrusions and grooves with scrapers, for which they wash the ferromagnetic sludge out of the grooves of the comb with a stream of water, and direct the stream of water into the lower part of the groove into side of the tilt of the comb. This is necessary for the collection and preparation of ferromagnetic sludge for remelting.

4. A mixture of water and sludge is directed into a centrifugal force field, in which the mixture acquires intensive rotational motion, and the aqueous and solid phases are separated, after which water is sent for reuse, and the ferromagnetic sludge with the remaining water is sent sequentially to a desiccant, container, followed by remelting ferromagnetic sludge. This is necessary to ensure the possibility of multiple use of water in the process and remelting of ferromagnetic sludge, which ultimately provides a waste-free and environmentally friendly process for cleaning liquids from ferromagnetic particles.

For installation:

1. The inlet and outlet pipes are made in the form of a rectangular gutter of non-magnetic material, the inlet pipe is equipped with partitions of non-magnetic material installed at the same distance from each other between the cylindrical magnetic disks. This is necessary in order to ensure that the liquid to be cleaned into the magnetic system of the installation is a thin layer over the entire width of the magnetic system, which ultimately will provide high installation performance and the degree of purification of lubricating oils, cutting fluids and other technical fluids to be cleaned of ferromagnetic particles.

2. The magnetic system is sludge-collecting elements made of the same size and representing cylindrical magnetic disks placed on a shaft, between which sleeves of non-magnetic material are installed. It is this design of the magnetic system that provides an increase in the productivity of the installation and the degree of purification of the liquid, since the liquid being cleaned passes not only along the outer cylindrical surface of the magnetic disks, but also along the channels between the disks.

3. The device for cleaning sludge-collecting elements is made in the form of an inclined comb made of non-magnetic material with protrusions and grooves with scrapers, the length of the protrusions of the comb is equal to the radius of the cylindrical magnetic disks, and the width of the protrusions is less than the length of the sleeve. These signs, as well as the signs described in the previous paragraphs of this section provide high efficiency of the process of cleaning cylindrical magnetic disks from ferromagnetic sludge.

4. In all gutters in the upper part of the comb, tubes of non-magnetic material are installed in the direction of inclination of the device for cleaning sludge-collecting elements, made in the form of an inclined comb of non-magnetic material with protrusions and gutters with scrapers. This feature provides a simplification of the process of moving collected sludge from magnetic disks into a special container.

5. The outlet pipe of the installation is connected through a pump to a hydrocyclone, the discharge pipe of which is connected in series with a desiccant and a container for collecting ferromagnetic sludge prepared for remelting, and the drain pipe of a hydrocyclone is connected to a water supply pipe to remove ferromagnetic sludge from a device for cleaning sludge-collecting elements made in in the form of an inclined comb of non-magnetic material with protrusions and gutters with scrapers. This is necessary to ensure the possibility of multiple use of water in the process and remelting of ferromagnetic sludge, which ultimately provides a waste-free and environmentally friendly process for cleaning liquids from ferromagnetic particles.

This design on the basis of experimental theoretical studies conducted by the authors is the most optimal. This is confirmed by the data presented in the table (for individual, group and centralized systems for the use of cutting fluids, depending on the volume of fluid used), which shows comparative specifications, various sizes of the prototype installation [4] and the proposed installation.

Comparative technical characteristics of installations Productivity, m ³ / h 6 12 thirty 60 120 180 240 300 Installation prototype [4] The degree of purification,% 90-97 90-97 90-97 90-97 90-97 90-97 90-97 90-97 Installed power, kW 0.2 0.3 0.5 0.75 one one 1,5 1,5 Overall dimensions, mm: length 510 510 550 600 650 750 750 1000 width 550 750 800 800 850 850 850 850 height 620 620 1000 1000 1100 1100 1500 1500 The working area of the magnetic system (cylindrical drum), m ³ 1,2 1.8 1.9 1.9 2.6 2.9 2.9 3,5 Suggested installation The degree of purification,% 95-99 95-99 95-99 95-99 95-99 95-99 95-99 95-99 Installed power, kW 0.2 0.3 0.5 0.75 one one 1,5 1,5 Overall dimensions, mm: length 510 510 550 600 650 750 750 1000 width 550 750 800 800 850 850 850 850 height 620 620 1000 1000 1100 1100 1500 1500 The working area of the magnetic system (cylindrical magnetic disks), m ³ 10,2 19.8 24.8 26.6 33.1 38,2 38.3 49.4

Note:

- the table shows the performance and degree of purification of the prototype installation and the proposed installation for the same sizes;

- the working area of the magnetic system is calculated taking into account the used bushings, the diameter of which is in the range of 60-70 mm and 110-120 mm, depending on the performance of the installation.

The number of cylindrical magnetic disks can be different depending on the specific operating conditions of the installation (the required performance and the degree of purification of water and oil coolants) and the real possibilities of placing the installation in a production room.

Thus, all the features indicated in the claims are necessary together to solve the problem of the invention.

A method of purifying a liquid from ferromagnetic particles is as follows.

The liquid to be cleaned of ferromagnetic particles is fed into the tank through a supply pipe made in the form of a rectangular gutter with a thin layer along the channels formed by partitions of non-magnetic material, installed at the same distance from each other between cylindrical magnetic disks, into the working area between the rotating magnetic disks and capacity base. Under the influence of a strong magnetic field, ferromagnetic particles (sludge) are attracted to rotating magnetic disks and carried out of the liquid. Further, the sludge on the disks falls under the squeeze roller, which presses the coolant out of the sludge layer by the force of a spring. With further rotation of the cylindrical magnetic disks, they are cleaned of sludge by means of a device for cleaning them, made in the form of an inclined comb of non-magnetic material with protrusions and gutters with scrapers. After removing sludge from magnetic disks, it (sludge) is washed off and sent to a hydrocyclone with the help of water supplied to tubes made of non-magnetic material, which are installed in the direction of the inclination of the device for cleaning sludge-collecting elements. Then, in the hydrocyclone, water and sludge are separated (the essence of the process is considered in [5]). Then the sludge enters the dehumidifier, and then into the container for collecting the ferromagnetic sludge prepared for remelting. Then the purified water is re-fed to the installation. The cleaned coolant is discharged from the installation tank through the outlet pipe.

Figure 1 shows a schematic diagram of an installation for cleaning liquids from ferromagnetic particles, figure 2 is a layout of a device for cleaning sludge-collecting cylindrical magnetic disks (side view).

Installation for cleaning liquids from ferromagnetic particles contains a container 1 (1, 2) for the liquid being cleaned with inlet 2 (figure 1) and outlet 3 (figure 1) nozzles (made in the form of a rectangular groove of non-magnetic material), a device 4 (figure 1, 2) for cleaning sludge-collecting cylindrical magnetic disks, tubes of non-magnetic material 5 (figure 1, 2), baffle 6 (figure 1), shaft 7 (figure 1, 2), sleeve 8 (figure .1) (made of non-magnetic material). The base 9 (figure 1) of the tank 1 for the liquid to be cleaned is cylindrical. The magnetic system is a hollow cylindrical magnetic disc 10 (figure 1). Outside the disks 10 (Figs. 1, 2), an squeeze roller 11 (Fig. 1) with a spring 12 (Fig. 1) is installed. A dehumidifier for drying ferromagnetic sludge, a container for collecting ferromagnetic sludge prepared for remelting, a hydrocyclone (Fig. 5).

The method is implemented on the installation for its implementation as follows.

The liquid to be cleaned of ferromagnetic particles is fed into the tank through a supply pipe made in the form of a rectangular groove with a thin layer along the channels formed by partitions of non-magnetic material (Fig. 3) installed at the same distance from each other between cylindrical magnetic disks, in the working area between the rotating magnetic disks and the base of the tank (Fig. 4. D is the diameter of the magnetic disk, d is the diameter of the sleeve, h ₁ is the thickness of the magnetic disk, h ₂ is the length of the sleeve). Under the influence of a strong magnetic field, ferromagnetic particles (sludge) are attracted to rotating magnetic disks and carried out of the liquid. Further, the sludge on the disks falls under the squeeze roller, which presses the coolant out of the sludge layer by the force of a spring. With further rotation of the cylindrical magnetic disks, they are cleaned of sludge by means of a device for cleaning them, made in the form of an inclined comb of non-magnetic material with protrusions and gutters with scrapers. After removing sludge from magnetic disks, it (sludge) is washed off and sent to a hydrocyclone with the help of water supplied to tubes made of non-magnetic material, which are installed in the direction of the inclination of the device for cleaning sludge-collecting elements. In a hydrocyclone, water and sludge are separated (the essence of the process is considered in [5]). The purified water is re-fed to the installation, and the ferromagnetic sludge with a part of the water is sent to a dehumidifier, then to a container for collecting the sludge prepared for remelting. The cleaned coolant is discharged from the installation tank through the outlet pipe. The process diagram is presented in figure 5.

The invention provides for the possibility of using cylindrical magnetic disks separately (outside the magnetic installation system) by variously installing them along the direction of the liquid being cleaned, followed by periodic replacement of magnetic disks with sludge with magnetic disks with cleaned magnetic elements.

The technical and economic effect of the proposed method for cleaning liquids from ferromagnetic particles and installation for its implementation is to use them to clean cutting fluids (coolant), restore the quality of lubricating oils by the content of ferromagnetic impurities, other technical fluids and oils used as coolant when turning, milling, drilling, blade processing, grinding, honing, superfinishing and other technological operations and metal processing processes that are characteristic kterizuyutsya large static loads, high temperatures, exposure to the material being processed in the cutting tool, forging and rolling equipment.

Literature

1. RF patent N2027473, B01D 35/06, B03C 1/00, 1995.

2. Application of Germany N2710005, B01D 35/06, 1978. - method.

3. RF patent N2104747, B01D 35/06, B03C 1/20, 1998 - prototype method.

4. RF patent N2106896, B01D 35/06, B03C 1/00, B.I. N8, 1998. - prototype installation.

5. Mustafaev A.M., Gutman B.M. "Hydrocyclones in the oil refining industry." - M .: Nedra, 1981. - 260 p.

Claims (2)

1. A method of purifying a liquid from ferromagnetic particles, including supplying a liquid to be cleaned into a container, passing it through a magnetic system, cleaning magnetic sludge collection elements from ferromagnetic particles or sludge, characterized in that the liquid to be cleaned is guided through an inclined inlet pipe made in the form of a rectangular gutter thin layer along the channels formed by partitions installed at the same distance from each other between the cylindrical magnetic disks and along the outer cylindrical surface The characteristics of magnetic disks rotating clockwise relative to the direction of movement of the liquid being cleaned remove ferromagnetic particles from the magnetic disks with a device for cleaning sludge-collecting elements made in the form of an inclined comb made of non-magnetic material with protrusions and grooves with scrapers, wash off the ferromagnetic sludge from the grooves of the comb with a stream of water, in this case, a stream of water is directed to the lower part of the trough towards the tilt of the comb, a mixture of water and sludge is sent to the field of centrifugal forces, in which the mixture acquires and intensive rotational motion, the water and solid phases are separated, after which the water is sent for reuse, and the ferromagnetic sludge with the remaining water is sent sequentially to the desiccant and container, followed by re-melting of the ferromagnetic sludge. 2. Installation for cleaning liquids from ferromagnetic particles, containing a container for the liquid to be cleaned, the base of which is made of a cylindrical shape, with inlet and outlet pipes, a magnetic system with sludge-collecting elements, a device for cleaning sludge-collecting elements, characterized in that the inlet and outlet pipes are made in in the form of a rectangular gutter of non-magnetic material, the inlet pipe is equipped with partitions of non-magnetic material installed at the same distance from each other and between sludge-collecting elements made in the form of cylindrical magnetic disks of the same size, placed on the shaft with a flat, between which sleeves are made of non-magnetic material, while the holes in the magnetic disks and bushings are made corresponding to the shape of the shaft with a flat, a device for cleaning sludge-collecting elements made in the form of an inclined comb of non-magnetic material with protrusions and gutters with scrapers, and in all gutters in the upper part there are tubes of non-magnetic material in a hundred the tilt of the comb, while the outlet pipe of the installation is connected through a pump to a hydrocyclone, the discharge pipe of which is connected in series with a desiccant and a container for collecting ferromagnetic sludge prepared for remelting, and the hydrocyclone drain pipe is connected to a water supply pipe to remove ferromagnetic sludge from the gutters.

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