DE19753785A1 - Ferromagnetic separator - Google Patents

Abstract

Ferromagnetic material is separated according to the physical Curie temperature in the finest possible electromechanical temperature increments, preferably being a hundredth to a thousandth degree Celsius increments, and is then deposited in sorting containers of different temperatures for further processing. The special program ensures that the temperatures are controlled up to a thousandth degree Celsius so that a characteristic of the material is established by its physical properties.

Description

The invention relates to a device Fig. 1 to pulverized, powdered crystal mixtures, sublimed, liquid or gaseous ferromagnetic material (Fe.- material called, even if it is eg. To Ni.-containing material Fe.-containing crystals or liquids Finely graduated Curie temperature level to separate and sort.

In the manufacture of melts, crystallize or in Sintering ferromagnetic material have the molecules Chains or crystals in a mass are not the same Physical properties, due to the fact that Mix materials not evenly in a melt, Sinter mix and crystal mix not uniform are distributed or evenly diffused.

The object of this invention is based on the so-called Fe. Material to remunerate and specify and Curie. Temperature, and thus the Curie. Temperature range and temperature knik within narrow limits to move from a hundredth of a degree Celsius. And thus the upper Curie. temperature range with little energy expenditure of ferromagnetic material.

I am familiar with the conventional ferromagnetic Materials are designed such. B. ferrite cores for the High frequency are manufactured as possible as that Curie. Temperature effect as late as possible or if possible not at all when heated by high frequency and Current flow begins.

It is also known that the magnet production Curie. Temperature effect and also with plastic bound Magnets in operation due to ambient heat problems Pop up. Before my registrations (AKz.) I was in matters Curie. Tmp. Effect is not known to ever have this effect in lower temperature ranges would be sought, even less that this Curie.-Tmp.-effect of someone improves would have or in the form upper and lower temperature range the Curie. temperature effect closer together.

If the Curie. Effect sets in beforehand in technology it doesn't matter whether the permeability curve is dependent slightly inclined from the temperature in the range of several degrees. Celsius is running down or abruptly in the range of one grad. Celsius jumps down, which affects who the curve arrives at a certain temperature that the Fe.-Ma material is no longer attracted to a magnet.

However, those made in the Fe separator Materials are special materials that are mainly for the Inventions such as B. Fe. Drive (Akz. 19751365.4), generator (Akz. P4429404.0), solar motor (Akz 197 20 969.6) and motor  (AKz. 197 14 427.6) Curie. Temperature effect Movement device (Akz. 197 21 349.9) used and the Technical utilization of the Curie. Temperature effect the French physicist Pierre Curie at Eisen in 1894 discovered to push ahead. According to my knowledge and Researches this effect as an uncomfortable one A by-product in technical devices and also in books described known. For example with computers with Magnetic babble storage (magnetic bubbles) or ferrite core storage If the temperature rises due to the Curie.-Tem temperature effect failed. Even with transmitting and receiving systems such an effect is usually not desired because Problems with the frequency stability of the resonant circuits (Ferment kernels) occur above the Curie. Temperature. Also P. Curie discovered a temperature point in crystals above this temperature the piezoelectric effect the so-called Curie point. The two Temperature points representing the electrical interval include, e.g. B. Signet salt has a Curie point of -16 and +24 degrees Celsius, which does not match the Curie. temperature of ferromagnetic materials is to be confused.

The operation of the Fe. Separating device is inventively solved so that the Fe. Material is subjected to a test before the separation in order to first determine the upper and lower Curie. Temperature range of the Fe material, so that the user program can save the correct temperatures in the form of a curve for the separation process. Depending on the temperature (x-axis) and the attraction force to a magnetic field (y-axis) in Kp, Joule, or the paramagnetic can be suspended in a pulling coil while the temperature is below to above the Curie. Has passed through temperature, which then results in a curve approximately as shown in FIG. 1 No. 17 on the screen of the Fe. Separating device. This determined curve is stored in computer No. 14 and keyboard No. 18. If a sintered material is used, Fig. 1 No. 1, it is crushed microfine because after sintering different diffused particles with different Curie. Temperature start and end values are present, which can even be below and above the determined curve of the starting material.

The Fe . Separator Fig. 1 has a double thermo-mirrored wall No. 12 as it is known for thermos bottles. The motors with No. 4 of the blower or spray motor (e.g. liquid), No. 7 servomotor with adjusting spindle No. 10 and the circulating air blower No. 15 can be attached outside the Fe-separating device, the power transmission can be transmitted magnetically as is usual with laboratory agitators, because otherwise the windings of the motors could burn. The inside of the Fe. Separation device is heated one day before use with the heating element Fig. 1 No. 8 to about 60 degrees Celsius higher than the actual Curie. Temperature kink. The computer control monitors the interior of the Fe. Separating device with the aid of a sensor Fig. 1 No. 13. In the best case, a protective gas is used which has good thermal conductivity, so that the internal temperature is exactly the same everywhere. The insulation and the outside temperature are chosen so that the inside temperature drops by a tenth of a degree every two hours or, depending on the program, rises or the temperature remains precisely controlled.

The computer Fig. 1 No. 14 has various programs. Program 001 can e.g. B. while the interior of the Fe. Separating device rises very slowly from 200 degrees Celsius to 200.03 degrees Celsius, the container holder Fig. 2 with the No. 2 is moved by the servo motor so that the tube No. 11 is exactly over the collecting container stands for the temperature 200.03. Now non-magnetic material falls into this container while the still magnetic material from tube No. 6 with the aid of blower No. 4 passes through tube No. 5 into vortex area No. 9 and in area No. 16 (if not from El. -Magnet No. 3 attracted.) The part of the Fe. Material falls towards the tube exit No. 11 if it is above the Curie. Temperature. While now the residual material no. 1, which is below the Curie. Temperature, the path no. 6 to no. 4 to no. 5 to no. 9 to no. 16 then finally sticks to the electrical magnet no. 3 then the whirling up in area No. 9 is stopped and the el.-magnet is switched off and a probe in area No. 11 detects that no Fe.-material falls into the container. So the container that is supposed to collect the Fe.-Material with the temperature 200.04 is moved under the pipe No. 11. And all this while the temperature of the interior increases very slowly linearly etc.

Another program can work in a very slow way the magnetic portion of the Fe material decays with the help the coil No. 3, whereby the pipeline No. 6 must be exchanged with pipeline No. 11. So now the No. 6 is passed into the separation container No. 2 and the Outlet No. 11 must be directed to blower No. 4. How it works B. at 250 degrees Celsius is all material non-magnetic. With linear cooling, little by little various particles are magnetic and are transferred via tube No. 6 thrown into the separation container No. 2. During the temperature gradually falls by a tenth of a degree Celsius, and the Actuator No. 7 depending on the program to the right or at  the process containers drop the process temperature (proportional to the temperature drop time to the left pushes.

With the addition of crystals. The Fe material separated in this way (Curie temperature, for example 200.05 degrees Celsius) can then be processed further, as in FIG. 6 No. 1 as a foamed aerosol (spaces filled with a gas) or foamed and the empty spaces are filled with a thermoplastic in order to be subject to the gas volume law even better. However, a normal metal or sintered metal can also be embedded in the disordered crystal mixture, FIG. 6, No. 1. It should be noted that the Curie point of the crystal material is always higher than the upper Curie temperature range of the Fe material, see above that the piezo effect in the area of the upper and lower Curie. temperature is fully effective. FIG. 7 shows how the Fe. Material and the crystal mixture are polarized at approximately 1.5 kilovolts per millimeter in order to produce a piezo crystal with ferromagnetic properties by means of a subsequent sintering process. Fig. 6 No. 26 shows as arrows in the mixture the still unordered crystals and ordered ones in Fig. 7. The crystals could already be magnetic by nature . Fig. 6 Fig. 7 No. 27 or even synthetically diffused with Fe material so that one would not have to integrate the Fe materials. A Fe.-Material No. 1 and ferromagnetic crystal can also be sintered together in order to improve the ferromagnetic properties of the piezoelectric finished crystals.

The Piezofertigkristall Fig. 8 No. can be z. B. give an alternating voltage, the prerequisite being that it is in a thermo container already at the lower Curie. B. 200.03 degrees Celsius preheated and temperature is still controlled. As a result of the fact that the piezo crystal now generates an overpressure and underpressure so that the Fe.-Material Fig. 8 No. 1 is heated in frequency to above and below the Curie. Temperature, he lets the magnetic flux flow from No. 30 to 31. This unit can be called a Curie switch, which can be used in many different ways. For example, as a switch that can be used to switch superconducting magnets or so-called frozen magnets with a high Tesla value. Also in a novel car the ferromagnetic z. B. 6 cylinders with the unit Fig. 8 one after another - controls the electrodes Fig. 8 No. 29 and No. 28 via an ignition distributor. (Similar to registration AKz. 197 21 349.9).

The Fe. Material as FIG. 7 as Fe. Crystal mixture can be roughly ground after the Fe. Separation process and again sent through the Fe . Separation device Fig. 1 No. 1 to Fe material created by the high-temperature sintering process Changes in the range of the Curie. Temperature, are sorted out. It is also possible to polarize the Fe.-crystal mixture (also called abbreviated Fe.-material.) After the separation process and to press it together with heat-resistant adhesive instead of sintering it again.

This granular material could be used in (Akz. 197 51 365.4 described, or how (Akz. 197 20 369.6 a rotating Fe. Crystal disc (ring.) Which has many electrodes in radiation form, on which grinders grind them above and below similar to Fig. 8 No. 29 No. 28 (so that the surface of the grinder would make at least one eighth of the ring surface non-magnetic due to the Curie effect.

In Fe-materials Fig. 3 in mini spherical shape materials could be used that would be arranged so that at warm-up time X from outside No. 19 to inside No. 23 All Fe.-Ma material layers become non-magnetic. This would happen if No. 19 = 200.09, No. 20 = 200.08, No. 21 = 200.07, No. 22 = 200.06, No. 23 = 200.05 the outer Fe.-Layer No. 19 to approx. 200.10 degrees Celsius would have risen The temperature gradation of the externally heated ball is therefore graded from the outside to the inside according to the Curie temperature material. Fig. 4 Fe.-Material No. 1 should have the highest Curie.-Temperature value at No. 23 and the lowest at No. 19 in order to get through the infrared lamp No. 24 at time X from the heat flow from left to right (almost all at the same time) to become non-magnetic.

Fig. 5 shows the Fe. material decreasing from a hot metal no. 25 also of Nos. 23 to no. 19 hundredths of a grad.-Cel SIUS each in the upper Curie. temperature value. Ideal for an engine piston (acc. 197 21 349.9) that is warmed up almost simultaneously from the outside in. If this is not the case and the Fe. Material is made of an unseparated ferrite material that is not z. B. is graduated in temperature from left to right, a higher temperature dose is required to migrate through the Fe. Material from left to right.

The purpose of the Fe. Separating device is to keep the Curie. Temperature kink in narrow temperature. B. The ideal would be a thousandth of a degree Celsius between the upper and lower Curie temperature. Basic research into the Curie effect should also be promoted with the help of the Fe separator. So that the Curie switch Fig. 8 could be compared to a transistor, no. 28, no. 29 would use (also in terms of energy) of the base and no. 30 (switching power moderately.) With the Kolektor and no. 31 compared to the emitter .

Claims (7)

1. Fe separator Fig. 1 for separating ferromagnetic material in powdered to coarse granules, sublimed, gaseous, liquid, crystalline and in mixed form such as. B. Fig. 6, characterized in that the Fe. Material to be separated according to the physical Curie. Temperature into feasible finest temperature steps El. Mechanical Fig. 1 No. 3 preferably ideal would be a hundredth to a thousandth of a degree Celsius Steps and then for further processing in sorting containers of different temperatures Fig. 2 No. 2 are stored. 2. Fe-separating device according to claim 1, characterized in that separate programs ensure that the temperatures are regulated down to a thousandth grad.-Celsius within the device Fig. 1, thereby to achieve that a characteristic of the to be processed Fe.-Material is created around its physical in particular the Curie.-Temperature characteristic curve Fig. 1 No. 17, characterized in that special attention is paid to the temperature kink in which the Curie.-temperature kink is artificially drawn out to make it better to be able to edit. 3. Fe-separation device according to claim 1., 2., characterized in that the Fe. Separation device sits in a type of thermal housing Fig. 1 No. 12, as it can be compared with a commercially available thermos for drinks. As a result, the temperature transitions run very slowly, so the servomotor Fig. 1 No. 7 has a lot of time to move around the spindle No. 10 so that the correct Fe.-material container Fig. 1 No. 2 under the pipe No. 11 to slide. In Fig. 1 No. 1 Fe.-Material is whirled up in area No. 9 and falls past the El.-Magnet No. 3 depending on the temperature and Curie.-Temp.-Material it is attracted to No. 3 or it falls through pipe no. 16 to no. 11 pipe end into the respective material container no. 2. 4. Fe. Separation device according to claim 1, 2, 3, characterized in that the Fe. Separation device can be connected upstream of different work processes, as in Fig. 3 No. 1, Fig. 4 No. 1, in figure and in as Fig. 6 No. 1 to produce multi-layer different Fe. starting material with it. 5. Fe. Separating device according to claim 1, 2, 3, 4, characterized in that Fe. Material made of several materials such as. B. ferromagnetic mixtures Fig. 6 of natural crystal, synthetically produced crystal and with ferromagnetic arrosil, which can be filled with gas or plastics and admixtures of ferromagnetic metals, ceramics, liquids, gases which are polarized by high voltages Fig. 7 No. 29 No. 28 can then be sintered Fig. 8. 6. Fe. Separation device according to claim 1 to 5, characterized in that an automated manufacturing chain can be connected downstream of the Fe. Separation device, which can be controlled and monitored by means of the computer Fig. 1 No. 14 to the products Fig. 3 to Fig. 8 to be able to complete. 7. Fe-separating device according to claim 1 to 6 characterized that I have a claim Figure 8 on the so-called, "Curie switch" of electrodes No. 29 No. 26 can be controlled and the piezoelectric Curie. Temperature effect triggers, claim.