PL193155B1 - Method of separating magnetic admixtures from liquid, gazeous and particulate solid media and apparatus therefor - Google Patents

Abstract

The invention relates to the technology of the magnetic separation of materials. Method consists in the removal of magnetic particles from the liquid, gaseous and friable media with the use of the precipitant elements via influence on the medium of a heterogeneous magnetic field from the side of magnetic system located inside the precipitant elements. The flow of medium is formed taking into account the topology of magnetic field, in this case it is directed thus, that it goes around zones with the weak magnetic field, from which precipitation of the magnetic particles is not ensured. Method realizes in the separator, which includes housing with the nonmagnetic cover, in which is located the magnet block in the form of the precipitant elements, consisting of the magnetic system, assembled from the permanent magnets and the concentrators, and nonmagnetic shell, connected with the cover, the collectors of supply and outlet of the cleaned medium. Due to that the magnet block is additionally equipped with elements, which are the distributor-and-shapers of the flow of medium in the volume of the housing of separator, the favourable conditions of precipitating the magnetic particles are formed, which raises the effectiveness of the work of separator.

Description

Description of the invention

The subject of the invention is a method and a device for separating magnetic admixtures from liquid, gaseous and free-flowing environments that adversely affect the quality of the base product.

It is known to separate magnetic impurities from fluid environments by influencing the environment with a magnetic field produced by a permanent magnet placed inside a cylindrical thick-walled soft magnetic steel housing. The disadvantage of this solution is the low efficiency of the separation of magnetic admixtures and the ineffective use of the mass exchange surface area between the cylindrical deposition element and the environment to be cleaned.

It is also known from US Pat. 5,043,063 a method of separating magnetic particles from fluid environments using embedding elements by means of the environmental impact of a non-uniform magnetic field from a magnetic system. The magnetic system is arranged inside the mounting elements. The disadvantage of this method is that its implementation cannot ensure high efficiency of the separation of magnetic impurities and the maximum use of the magnetic field energy. The magnetic system generating the magnetic field is characterized by an uneven distribution of the magnetic forces of the field in the volume of the purification environment along each of the mounting elements, creating a space of maximum magnetic action and spaces where the magnetic action is insufficient. On the basis of observations, it was found that along the length of the mounting elements there is an abnormal system of forces between the magnetic attraction forces (Fm) of the particles to the deposition elements and the hydrodynamic force (Fc), which contributes to the shift of magnetic impurities along the stream of the treated environment. The effective separation takes place by performing the Fm> Fc condition, which is not ensured in the known solution.

Surprisingly, it turned out that by using special sections, it is possible to separate the stream of the treated environment into individual smaller streams and to properly direct them to the zones of embedding elements with maximum magnetic force, which significantly contributed to obtaining optimal parameters of the environment being treated.

The essence of the method of separating magnetic admixtures from liquid, gaseous and free-flowing environments, according to the invention, is that the stream of the environment to be treated is first divided into streams and then directed directly to the zones of maximum operation of the deposition elements.

The essence of the device for separating magnetic admixtures from liquid, gaseous and powdery environments, according to the invention, is to equip the system of mounting elements of the magnetic block with profiles of the stream of the environment to be treated. The sections of the stream of the environment to be treated are in the form of bars with a curvilinear surface, and the distance between the convexities of the section surface is equal to the distance between the ferromagnetic elements located in the mounting elements. The profiles of the stream of the environment to be treated are made with a successive arrangement of the magnetic and non-magnetic material. In a variant of the invention, the profiles of the stream of the environment to be treated are in the form of curved walls with protrusions. In the second variant of the invention, the profiles of the stream of the environment to be treated are in the form of non-compact curved walls. In another variant of the invention, the magnetic arrangement of the mounting elements comprises permanent magnets with radial magnetization. In a further variant of the invention, the side walls of the casing have a curvilinear surface and constitute a system of shapes of the stream of the environment to be treated.

At least one mounting element of the plurality of these elements is movable in relation to the non-magnetic diaphragm.

The advantage of the solution according to the invention is the optimal efficiency of separating magnetic admixtures from various environments, both liquid, gaseous and loose.

The subject of the invention has been explained in the drawing, in which Fig. 1 shows a diagram of a device in which the profiles of the stream of the environment being treated are in the form of bars and diaphragms, and Fig. 2 shows a diagram of the device in which the profiles of the stream of the environment being treated are made in the shape of a curved wall, while Fig. 3 shows a diagram of a device in which the profiles of the stream of the environment to be treated are made in the shape of non-compact curvilinear walls, and Fig. 4 shows a diagram of the device in which the profiles of the stream of the environment to be treated are made in the form of a pouring distributor, and Fig. 5 shows a diagram of the device with the side walls of the housing in the shape of a curvilinear surface, and fig. 6 shows a diagram of the distribution of the magnetic field in space around the mounting element with a section made of a non-magnetic material of the device shown in fig. 1, while fig. of the stream of the environment being treated with an indication of the magnetic field deposition forces at points opposite to the ferromagnetic elements, in the device housing without additional elements, and Fig. 8 shows a diagram of the distribution of the stream being cleaned in the device housing with additional elements in the form of sections.

The device for separating magnetic admixtures from liquid, gaseous and free-flowing environments according to the invention has a housing 1 connected to a non-magnetic cover 2 and an inlet manifold 3 and an outlet manifold 4 of the environment to be treated. Inside the housing 1 there is a magnetic block consisting of mounting elements 5 having a non-magnetic diaphragm 6 and a magnetic system consisting of permanent magnets 7 and ferromagnetic elements 8.

Inside the casing 1 there are also profiles 9, by means of which the stream of the treated environment is divided into smaller streams and then directed directly to the zones of the mounting elements 5 of the magnetic block having the maximum magnetic force.

The profiles 9 are in the form of bars with a curvilinear surface, the distance between the convexities of the surface being equal to the distance between the ferromagnetic elements 8 placed in the mounting elements 5.

In a variant of the invention, the sections 9 are in the form of curved walls with protrusions.

In the second variant of the invention, the sections 9 have the form of non-compact curved walls.

In another variant of the invention, the side walls of the housing 1 have a curvilinear surface and constitute a system of shapes 9 of the stream of the environment being treated.

In a further variant of the invention, the magnetic arrangement of the mounting elements 5 comprises permanent magnets 7 with radial magnetization.

In this variant, the most uniform distribution of the magnetic field in the working space around each of the mounting elements 5 is achieved, so in this case a minimum amount of use of the profiles 9 of the environment being treated is required.

The method according to the invention is presented in an exemplary embodiment. The environment to be treated is led to the housing 1 through the inlet manifold 3 and is divided by means of sections 9 into smaller streams. Streams of the purified environment, flowing around the mounting elements 5, deposit magnetic impurities on the diaphragms 6, and the cleaned environment is discharged through the collector 4 outside the housing 1 of the device.

In a variant of the invention, in the case of cleaning loose environments (Fig. 4), the profile 9 is made with a successive arrangement of magnetic and non-magnetic material, e.g. a non-magnetic profile 10 and ferromagnetic rods, which are approximated to the deposition elements 5. In this case, a part of strongly magnetic admixtures it settles on ferromagnetic rods, increasing the efficiency of the device and the amount of retained admixtures. In a variant of the invention, in the case of the curvilinear surface of the side walls of the casing (Fig. 5), the function of the profiles 9 of the stream of the environment to be treated is performed by the casing itself, by means of which the zones which do not meet the condition of magnetic impurities deposition (Fm> Fc) are switched off.

The use of the separation device allows to influence the physical parameters of the environment, e.g. viscosity, surface tension, dialectical permeability of fluids, reducing the ability of the circulating water to deposit limescale on the heat transfer surfaces, reducing its corrosive properties, etc.

Claims (9)

Patent claims 1. The method of separating magnetic admixtures from liquid, gaseous and powdery environments with the use of embedding elements by acting on the environment of a non-uniform magnetic field, characterized in that the stream of the environment to be treated is first divided into streams and then directed directly to the zones of maximum operation of the depositing elements ( 5). PL 193 155 B1 2. Device for separating magnetic admixtures from liquid, gaseous and powdery environments, including a housing with a non-magnetic cover, a magnetic block consisting of embedding elements having permanent magnets, ferromagnetic elements and a non-magnetic diaphragm, and inlet and outlet collectors of the environment to be treated, characterized in that the system the mounting elements (5) of the magnetic block are equipped with profiles (9) of the stream of the environment being treated. 3. The device according to claim 1 2. The pipe according to claim 2, characterized in that the profiles (9) of the stream of the environment to be treated are in the form of bars with a curvilinear surface, the distance between the convexities of the surface of the profile (9) being equal to the distance between the ferromagnetic elements (8) located in the mounting elements (5). 4. The device according to claim 1 2. The method of claim 2, characterized in that the profiles (9) of the stream of the environment to be treated are made with a successive arrangement of magnetic and non-magnetic material. 5. The device according to claim 1 2. The method of claim 2 and 4, characterized in that the profiles (9) of the stream of the environment to be treated are in the form of curved walls with protrusions. 6. The device according to claim 1 The method of claim 2, characterized in that the profiles (9) of the stream of the environment to be treated are in the form of non-compact curved walls. 7. The device according to claim 1 2, 4 and 6, characterized in that the magnetic arrangement of the mounting elements (5) comprises permanent magnets (7) with radial magnetization. 8. The device according to claim 1 2, 3, 4, 5, 6 and 7, characterized in that at least one element of the assembly of mounting elements (5) is displaceable in relation to the non-magnetic diaphragm (6). 9. The device according to claim 1 2. A method according to claim 2, characterized in that the side walls of the housing (1) have a curvilinear surface and constitute an arrangement of profiles (9) of the stream of the environment to be treated.