JPS6144533B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an apparatus for removing impurities from a fluid medium, and more particularly to a separation apparatus used to separate a fluid medium from particulate impurities. This separation device is used in the chemical industry, food industry, pharmaceutical industry, machinery industry, power industry, and other industries to separate fluids from fine particles with a size of about 0.1 to 10 microns, which account for 10 ^-5 to 10 ^-8 of the total mass. used as a means.

Various devices are known that are used to purify fluids by means of magnetic or electric fields, which remove particulates present in the fluid. For example, it may include a cylindrical housing separated by an internal partition wall arranged to form two chambers whose cross-section is part of a circle, one chamber filled with an overpacking of ferromagnetic material. Devices for separating fluid from particulates are known (see USSR Inventor's Certificate No. 698,658), in which the chamber is filled with nothing and the other chambers are not filled with anything. In this device, a magnetizing device in the form of a solenoid surrounding the housing from the outside generates a magnetic field around the housing. A space present at one end of the housing connects the chambers to each other, and a pipe at the top of the other end of the housing provides for inlet and outlet of the fluid medium. When the fluid medium enters the empty chamber, it is exposed to the magnetic field generated in the chamber, and as a result, the ferromagnetic particles contained in the fluid grow large and when they enter the connecting space. Continue to grow. Inside the chamber containing the ferromagnetic packing, the ferromagnetic particles are separated from the fluid.

However, this known device is not able to separate charged particles that do not belong to ferromagnets from the fluid medium. Only some of these charged particles are removed, and only those attached to the ferromagnetic particles are removed by chance.

It is therefore an object of the present invention to provide a separation device that can improve the degree of purification and the quality of the product by separating even charged particles that do not belong to ferromagnetic materials from a fluid medium.

This purpose consists of a housing, a partition placed inside the housing to form two chambers, a magnetizing device for generating a magnetic field in the housing, and a magnetizing device provided at one end of the housing to connect both chambers to each other. a space and a pair of pipes provided at the other end of the housing for supplying and discharging a fluid medium between the chambers, one of the chambers being filled with an overpacking of ferromagnetic material. , in a separation device for separating a fluid medium from impurity particles, by filling the other of the two chambers with an overpacking of ferroelectric material.

When the ferromagnetic packing does not naturally exhibit electrical polarization, it is convenient to provide electrodes in other chambers.

In order to intensify the magnetizing effect experienced by the ferromagnetic particles, it is also expedient to place a ferromagnetic packing in the chamber filled with the ferroelectric packing.

If it is important to keep the voltage applied between the electrodes as short as possible, it is more advantageous to use an electret as the ferroelectric packing.

The advantage of this separation device is that the ferroelectric material exhibits permanent electric polarization and high dielectric constant, making it extremely difficult to apply an external electric field between the components of the ferroelectric packing in other chambers. This results in a very strong and extremely uniform electric field. The electric field thus generated creates favorable conditions for removing non-ferromagnetic charged particles from the fluid passing through the ferroelectric overpacking. Therefore, while separating the ferromagnetic particles from the fluid medium passing through the ferromagnetic packing, the charged particles are also removed in the ferroelectric packing, resulting in a higher degree of purification and improved product quality. It gets expensive.

The electrode to which the ferromagnetic packing is attached is
This is an effective means when ferroelectric packing no longer exhibits natural electrical polarization. These electrodes control the function of the ferromagnetic packing to ensure its operation, the electrical polarization of the packing to the desired degree, and the properties of the fluid medium and the particles contained therein. The degree of polarization can be changed depending on the nature of the polarization. Dual electrodes can also be provided to depolarize the ferroelectric packing so that regeneration of the ferroelectric packing and removal of separated particles is always possible. This makes it possible to shorten the downtime of the separator and lengthen the overcycle.

Another advantage of the separation device of the invention is that the chamber filled with ferroelectric packing is also filled with ferromagnetic packing. Ferromagnetic packing is a process in which ferromagnetic particles are pre-magnetized, the ferromagnetic particles adhere to each other to form large particles, and then the fluid medium containing the particles is inserted into the ferromagnetic packing. The magnetic field is strengthened locally so that it can enter the area. As a result, the degree of purity is high,
The quality of the product will be higher.

Making ferroelectric packing from electrets eliminates the need to constantly connect the electrodes to a power source.
All that is required in this case is to periodically depolarize the electret during the regeneration cycle and to briefly apply a voltage to the electrodes after regeneration to repolarize the electret and operate the separator. It is.

Hereinafter, the present invention will be explained in detail with reference to the drawings.

Referring first to FIGS. 1 and 2, the separating device has a cylindrical housing 1. In FIG. The housing 1 is arranged so that two chambers 3 and 4 whose cross section is part of a circle are formed inside the housing 1.
A partition wall 2 is arranged inside. The inside of the chamber 3 is filled with ferromagnetic material overpacking 5,
There is a ferroelectric overpacking 6 inside the chamber 4.
is filled. A space 8 at the lower end of the housing 1 interconnects the chambers 3 and 4, and pipes 9, 10 provided at the upper end of the housing 1.
respectively feed and discharge the fluid medium. A solenoid 7 is installed on the outside of the housing 1.
are arranged coaxially.

The separation device shown in FIGS. 3 and 4 consists of chambers 11, 12 having a cylindrical cross section and arranged concentrically with respect to each other, with the center of the inner chamber 12 being filled with a ferroelectric packing 6. Electrode 13
It is similar to the separation device shown in FIGS. 1 and 2, except that it is provided with a. The cylindrical wall of the chamber 12, which is made of a conductive material and is grounded by a grounding member 14, serves as the other electrode. The walls of chamber 12 also function as a partition between chambers 11 and 12.

The separating device shown in FIGS. 5 and 6 has two housings 15. The separating device shown in FIGS. Each housing 1
5 indicates two cylindrical chambers 1 arranged in pairs.
6,17. Those chambers 16, 17
Adjacent walls of serve as partition walls 18. The chambers 16, 17 of each chamber pair communicate with each other via a space 19 and a pipe 20. Chamber 1
7 is also provided with an even number of radial electrodes 21. Every other electrode 21 is connected to a different electrode of a power source (not shown). That is, adjacent electrodes 21 are connected to electrodes of different power supplies.
A feature of this embodiment of the separation device is that a ferromagnetic packing 22 is added to the ferroelectric packing 6. In this embodiment, the magnetization device consists of an electromagnet 23. This electromagnet 23 is composed of a winding 24 wound around a magnetic circuit 25.

Axial electrode 13 and radial electrode 21
and the ferromagnetic packing 22 added to the ferroelectric packing are applicable to the embodiments of the separation apparatus shown in FIGS. This is considered to be a characteristic of

The ferromagnetic packing 22 added to the ferromagnetic overpacking 5 and the ferroelectric overpacking can be balls, crushed chips and other small ferromagnetic materials. Those packing are
It must be corrosion resistant so as not to contaminate fluids. The ferroelectric overpacking 6 can be constructed of small pieces of barium titanate, germanium telluride, lithium niobate, bismuth titanate, and other ferroelectric materials, for example. The choice of which of these materials to use is determined by the nature of the fluid medium to be removed and the polarization effect exhibited by the supermaterial. In order not to weaken the effect of the magnetic field, the housings 1, 15 and the partition walls 2,
18 and the walls of chamber 12 are made of a non-magnetic material, preferably stainless steel or fluoreniplastic.

Next, the operation of this device will be explained. Magnetizer 7
(Figs. 1 to 4) or 23 (Figs. 5 and 6) is excited, the ferromagnetic packing 5 and the ferromagnetic packing 22 attached to the ferroelectric packing 6 are magnetized. At the same time, the voltage applied to the electrodes 13 (Figs. 3 and 4) or 21 (Figs. 5 and 6) electrically polarizes the ferroelectric packing 6 (if the packing 6 is not naturally polarized, , this polarization operation is done at a specific value). Through the pipe 9, the chamber 4 (Figs. 1 and 2), 12
(Figs. 3 and 4) or 17 (Figs. 5 and 6), the fluid enters the ferroelectric packing 6 and the space 8 (Figs.
) and through the ferromagnetic packing 5 contained in the chamber 3 (Figs. 1 and 2), 11 (Figs. 3 and 4) or 16 (Figs. 5 and 6).
Separate from charged particles and ferromagnetic particles. The purified fluid is discharged through pipe 10.

Electrode 13 (Figures 3 and 4) or 21 (Figures 5 and 6)
(Fig.) allows overworking to be controlled by varying the degree of electrical polarization of the ferroelectric packing 6 depending on the nature of the fluid medium and the nature of the particulate material. The packing 6 can also be regenerated by constantly depolarizing the ferroelectric packing 6 using the electrodes 13 or 21.

The ferromagnetic packing 22 (Figs. 5 and 6) added to the ferroelectric packing 6 allows the chamber 1 to
It is also possible to intensify the magnetic field generated within 7. This causes the ferromagnetic particles to become more strongly magnetized, causing them to move between the chamber 17 and the space 19.
While passing through the gap, the particles can be made to adhere more strongly to each other and become larger particles. In this case, it is clear that a higher quality product can be obtained since it is possible to achieve a higher degree of purification than with conventional techniques.

When the ferroelectric packing is made of electrets, the electrode 21 is only used when depolarizing the electret to regenerate the packing and when re-polarizing the depolarized electret. Connect to power.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view of a separation device according to the invention for separating a fluid medium from fine particles, having a chamber whose cross section is part of a circle and a magnetization device constituted by a solenoid; FIG. 1, FIG. 3 is a longitudinal section through a separation device similar to that of FIG. 1, with an axial chamber and an electrode provided in the inner chamber; FIG. 4; 3 is a sectional view taken along the line - in FIG. 3, and FIG. 5 is a longitudinal sectional view of a separation device of the invention having a cylindrical chamber, a radial electrode, a magnetization device including a magnetic circuit, and a magnetic field generator. 6 is a sectional view taken along the - line in FIG. 5. 1, 15... Housing, 2, 18... Bulkhead,
3, 4, 11, 12, 16, 17... Chiyamba,
5,22...Ferromagnetic packing, 6...Ferroelectric packing, 7,23...Magnetizing device, 8,19
... Space, 9 ... Supply pipe, 10 ... Discharge pipe, 13, 21 ... Electrode.

Claims (1)

[Claims] 1. Housing 1:15, two chambers 3,
Partition wall 2:1 arranged inside housing 1:15 to form 4:11, 12:16, 17
8, a magnetizing device 7:23 that generates a magnetic field within the housing 1:15, and a magnetizing device 7:23 that is provided at one end of the housing 1:15, and both chambers 3, 4: 11, 12:
Space connecting 16 and 17 to each other 8:19
and a pair of pipes 9, 1 provided at the other end of the housing 1:15 for supplying and discharging a fluid medium between the chambers 3, 4: 11, 12: 16, 17.
0 and one of both chambers 3:11:
16 is filled with overpacking 5 of ferromagnetic material, in a separation device for separating a fluid medium from impurity particles, the other of the two chambers is 4:1.
2:17 A separation device for separating a fluid medium from impurity particles, characterized in that a ferroelectric overpacking 6 is filled. 2. The separation device according to claim 1, characterized in that the chamber 12:17 is provided with at least a pair of electrodes 13, 14:21. 3. In the separation device according to claim 1 or 2, the chamber 17 filled with the ferroelectric packing 6 is filled with the ferromagnetic packing 2.
A separation device characterized in that it also contains 2. 4. The separating device according to claim 1, wherein the ferroelectric packing 6 is an electret.