UA10518U - Electromagnetic filter-separator - Google Patents

Abstract

Electromagnetic filter-separator contains cylindrical housing with inlet and outlet ducts, from outer side of which a winding is located, and ferromagnetic nozzles are placed inside, they are made in the form of spirals of magnetic material. Ferromagnetic body having flanges with the openings is located above winding.

Description

Description of the invention

A useful model refers to the field of agriculture, intended for the purification of dispersed 2 bulk materials from ferromagnetic impurities, such as crushed grain or flour, used in the food industry.

The known device contains a case with covers, an electromagnetic system and a block of concentrators (Ass. USSR

Mo1018717, IPKZ VO4S 5/12, VOZS 1/00, 1983.1.

The disadvantage of this device is that the working "magnetic" zone of particle capture is small due to unreasonable placement of concentrators and losses of magnetic field energy, which reduces the degree of purification of highly dispersed bulk materials.

The closest technical solution, chosen as a prototype, is an electromagnetic filter-separator, which contains a cylindrical body with inlet and outlet nozzles, outside of which there is a winding, and inside 75 ferromagnetic nozzles made in the form of spirals of magnetic material |Pat. Mo. 68105A Ukraine, IPC" VOZS 1/02, 2004).

But this device requires more energy when cleaning dispersed bulk materials from ferromagnetic impurities due to greater losses of the magnetic field.

The useful model is based on the task of creating an electromagnetic filter-separator, which has a cylindrical ferromagnetic frame with flanges with holes made in the form of Laval nozzles, placed symmetrically to the spirals, which makes it possible to evenly distribute the flow of dispersed bulk materials throughout the entire volume of the filter-separator, eliminate clogging bulk materials of the passages, reduce energy costs for the cleaning process by increasing the strength of the magnetic field in the capture zone and improve the quality of dispersed bulk materials that are cleaned. The problem is solved due to the fact that the proposed electromagnetic filter-separator contains a cylindrical body with inlet and outlet nozzles, outside of which there is a winding, and inside - ferromagnetic nozzles, made in the form of spirals of magnetic material according to the useful model, a cylindrical ferromagnetic is installed on top of the winding a frame that has flanges with holes.

The task is solved in the same way due to the fact that the holes of the flanges are made in the form of nozzles of Co. 20 Laval and are located in concentric circles above the ferromagnetic nozzles.

The task is solved in the same way due to the fact that the total cross-section of the holes in each flange is equal to the cross-section of the inlet and outlet nozzles, respectively. yu

Thus, the use of an electromagnetic filter-separator of this design will allow to increase the degree of purification of dispersed bulk materials from ferromagnetic impurities. The ferromagnetic frame will allow | "c) zv Reduce energy costs for the process of capturing impurities due to the strengthening of the magnetic field in the area of "- extraction, and the holes in the flanges in the form of Laval nozzles, concentrically located above the spirals, will evenly distribute the flow of dispersed bulk materials throughout the entire volume of the filter-separator and reduce the possibility of " "suspension" of material in the filter.

In fig. 1 shows the general view of the electromagnetic filter-separator. " 20 In fig. 2 section A fig. 1. -o

In fig. From view I fig. 1. c The electromagnetic filter-separator consists of a non-magnetic cylindrical body 1, with fixed inlet 2 and outlet Z nozzles. A winding 4 is placed outside the housing 1, above which a ferromagnetic frame 5 with flanges 6 and 7 is installed, and ferromagnetic nozzles 8, made in the form of 415 spirals of magnetic material, are fixed inside the housing 1. Flanges b and 7 have holes 9, which are created in the form of Laval nozzles and - located in concentric circles above ferromagnetic nozzles 8, and the total cross-section of the holes 9 in each flange 6 and 7 is equal to the cross-section of the inlet 2 and outlet Z nozzles, respectively. ("c") The device works as follows. sl Highly dispersed material contaminated with ferromagnetic impurities enters the "working" volume of the filter-separator through inlet pipe 2 and hole 9 of flange b. When the winding 4 is turned on at a constant voltage -th, a magnetic field is created, the lines of force of which are closed between the nozzles 8 in the longitudinal direction of the filter-separator, under the action of ponderomotive forces of which each ferromagnetic particle, having appeared in the "capture zone" of the filter-separator, will be attracted to the surfaces of the nozzles 8. The increase in the field strength in the "working" volume of the filter-separator at constant energy consumption is ensured by reducing the magnetic scattering fluxes with the help of the ferromagnetic frame 5 and flanges 6, 7. The purified highly dispersed material enters through the holes 9 in the flange 7 and the outlet pipe Z for other technological operations. The holes 9 in the flanges 6, 7 are located in such a way that the flow of dispersed material enters directly on the nozzles 8, which makes it possible to distribute it evenly over the entire volume of the filter-separator. The removal of trapped ferromagnetic particles is carried out by turning off the current in solenoid 4 at a complete stop of the technological process.

Claims (2)

Formula of the invention in 1. An electromagnetic filter-separator containing a cylindrical body with inlet and outlet nozzles, outside of which there is a winding, and inside - ferromagnetic nozzles, made in the form of spirals of magnetic material, which is distinguished by the fact that a cylindrical ferromagnetic frame is installed on top of the winding , which has flanges with holes. 2. Electromagnetic filter-separator according to claim 1, which differs in that the flange holes are made in the form of Laval bopels and are located in concentric circles above the ferromagnetic nozzles. C. The electromagnetic filter-separator according to claim 1, which differs in that the total cross-section of the holes in each flange is equal to the cross-section of the inlet and outlet nozzles, respectively. that 2 (ee) «- iv) «c) є - with . and? - ((c) 1 - 70 IR e) c 60 b5