CS215988B1 - A way of producing environmentally friendly technical gasoline - Google Patents

Abstract

The solution concerns the method of producing technical gasoline with a boiling point of 80 to 110 *C and 90 to 150 "C with a maximum content of n-hexane of 0.1% by weight and aromatic hydrocarbons of 0.01% by weight from reforming gasoline. The low content of n-hexane is achieved by rectification and combination of fractions of reforming gasoline. Aromatic hydrocarbons are removed by a combination of extraction distillation and adsorption on zeolites or extractive distillation and hydrogenation.

Description

The invention provides a device for determining the magnetic orientation of a magnetically conductive sample for determining a plane in which the directions of easy magnetization lie, for example in the shape of a sphere.

The devices used to determine magnetic orientation by determining the crystallographic axes by means of X-ray scattering require a specialized workplace equipped with expensive X-ray equipment, where special safety precautions are necessary to protect health. Measurement and evaluation is very time-consuming and, among other things, burdens the capacity of X-ray workplaces. Exposure of one sample takes 10 to 20 hours.

Further, there is known a device for determining the magnetic orientation of a magnetically conductive sample, consisting of a holder of a magnetically conductive sample and pairs of main magnetic field sources and a pair of auxiliary magnetic field sources alternately arranged around each other. The main magnetic field source pairs and the auxiliary magnetic field source pairs are disposed relative to each other.

A freely magnetically conductive anisotropic, for example spherical sample, is placed in the magnetic field, and the sample is positioned such that the axis of ease of magnetization coincides with the direction of the external magnetic field. In determining the magnetic anisotropy constants, it is necessary to find a plane determined by the directions of easy magnetization, i.e. to determine the magnetic orientation of the sample. To determine this plane, two magnetic fields, main and auxiliary, are used to determine the plane to be sought. The angle of the principal and auxiliary field vector must be greater than zero and less than π / 2, and it is advisable to approach the angle between the axes of easy magnetization of the material of interest. The alternating action of the main and auxiliary fields results in alternate shifting of two directions of easy magnetization to the directions of the main and auxiliary axes that determine the directions of the vectors of the main and auxiliary fields. The sample is gradually rotated to a position where the plane determined by the main and auxiliary field vectors is identical to the plane of easy magnetization. By marking this sample position, the desired magnetic orientation of the sample is obtained. Mechanical forces occur between the holder and the magnetic conductive sample, which reduce the accuracy of the measurement.

This drawback is eliminated by the device according to the invention. Its essence lies in the fact that a ferro-liquid is placed between the holder e with the magnetically conductive sample.

Ferro-liquid is a two-component liquid in which, in a dispersion medium, for example oil, water and the like, there is a dispersion fraction of solid ferromagnetics, such as pure iron, of such small dimensions and in such an arrangement as particles coated with oleic acid. in a magnetic field. Ferroalcohol does not allow direct contact of the specimen and holder when exposed to the magnetic field, as it is able to exert magnetic pressure at a small change in its viscosity and virtually eliminate undesirable mechanical forces between the specimen and holder, resulting in uncontrolled positioning errors plane. For example, to ensure accurate identification of the plane to be sought, non-magnetic jaws on the holder are pressed against the specimen during the application of magnetic fields, thereby mechanically securing its position. In this state, for example, a handling bar and the like can already be adhered to the sample. In order to achieve sufficient magnetic induction and homogeneity of the magnetic fields used, it is energetically and structurally advantageous to close these fields via magnetically conductive main and auxiliary poles with main and auxiliary coils connected to the power source via a mechanical or electronic switch.

The switch alternately connects the main and auxiliary coils at a suitable frequency to a direct current source. In order to achieve greater precision in the determination of the magnetic orientation of the sample, it is desirable that the device allow to vary to some extent the angle between the directions of the main and auxiliary field vectors. In practical agreement of the angle of the directions of easy magnetization and the directions of the magnetic fields, the movement of the sample will be minimal and in this state the searched plane will be determined with the minimum error.

For a sample whose shape is close to a sphere, which can be practically fulfilled, at least shape anisotropy is applied and the accuracy of the magnetic orientation determination is comparable to that of the X-ray method, but the measurement time is only a few minutes.

The invention is illustrated in more detail by way of example with reference to the accompanying drawing.

Sample holder 2 is located between a pair of main magnetic field sources 6 and a pair of auxiliary magnetic field sources 6, and a ferro-liquid 2 is disposed between the holder 1 and the magnetic conductive sample 2 and a pair of main magnetic field sources 6 and a pair of auxiliary magnetic field sources 6 are stored. adjustable. In the holder 6, a magnetically conductive sample 2 formed, for example, of a ferrite monocrystal, is held by magnetic pressures in the ferro-liquid 2. The main poles 4 with the main coils 4 determine the main axis indicating the direction of the vector of the main magnetic field. The auxiliary poles 2 with the auxiliary coils 8 determine the auxiliary axis indicating the direction of the auxiliary field vector. The main coil 8 and the auxiliary coil 8 are electrically connected to a switch 40 which alternately connects them to a direct current source 12 according to the frequency of the control voltage from the actuator 11. After the motion has stabilized, the magnetically conductive sample 2 is directed to the main and auxiliary magnetic fields, the jaws 13 are pressed against the magnetically conductive sample 2 to secure its position and allow the magnetic orientation given by the plane of the principal axis and the auxiliary axis to be indicated.

Claims (1)

A device for determining the magnetic orientation of a magnetically conductive sample, consisting of and around the holder of a magnetically conductive sample, alternately disposes of a pair of main magnetic field sources and a pair of auxiliary magnetic field sources, characterized in that between the holder (1) and the magnetically conductive sample (3) a ferro-liquid (2) is placed.