RU85478U1 - PLANT FOR PROCESSING RAW MATERIALS - Google Patents

Abstract

1. Installation for processing raw materials, including a loading hopper, a reaction chamber associated with a power source and with inlet and outlet pipes, the reaction chamber is made in the form of a housing in which electrodes are installed, characterized in that it is equipped with a device for collecting gaseous oxides and hydrides with a bubbler, and the loading hopper is equipped with an ultrasonic disperser, while the reaction chamber body is made in the form of a flat container, in the lower part of which there is an electrode designed to accelerate ECCA dissociation of water, and the upper part of the vessel having the inner surface material - positron source, used as a second electrode. ! 2. Installation for processing according to claim 1, characterized in that the electrode designed to accelerate the process of dissociation of water is made of a composite material based on boron nitride (B11N15) reinforced with ultrafine silicon carbide SiC and carbon fiber. ! 3. Installation for processing according to claim 1, characterized in that as the source material of the positrons use either Zn65, or Mn54 or Fe55.

Description

The proposed utility model relates to installations for processing raw materials, in particular, heavy petroleum feedstocks, and is intended for producing light fractions: diesel fuel, kerosene, gasoline, gas, and can be used in the utilization and processing of natural gas, biogas, incomplete stone products coal and waste, as well as for water treatment.

Known installations for thermomechanical cracking and hydrogenation of hydrocarbons in liquid or solid form, carbonates, lime, oil shale and sand, oily residues of oil refineries, etc.

A known installation used in the method of thermomechanical cracking and hydrogenation of hydrocarbons (see RF patent 2131903, according to class C10G 1/06, 1994)

A known device includes a feed hopper and a reactor connected to a feed unit.

However, the efficiency of this installation is insufficient.

The closest in technical essence is a device for the partial oxidation of lower hydrocarbons in an electric discharge, including a loading hopper, a reaction chamber associated with a power source and with inlet and outlet nozzles, the reaction chamber being made in the form of a housing in which electrodes are installed (see RF patent No. 2088565, according to class С07С 27/14, 1995)

The known device uses a plasma-chemical reactor with an electric discharge, which can create a low-temperature nonequilibrium plasma, where the gas has a temperature close to room temperature and the electrons in the plasma have an energy (2-5 eV) sufficient for the chemical activation of molecules of natural gas and oxygen, or air.

In this case, the plasma chemical reactor is equipped with a gas supply system containing a cylinder with natural gas and a cylinder with oxygen, shut-off valves and a tee to obtain a mixture of gases.

A disadvantage of the known design are:

- the complexity of the design due to the presence of additional devices necessary for the introduction of substances and the production of atomic hydrogen and oxygen;

- high energy consumption of the installation due to the plasma-chemical process;

- there is no possibility of preparing the feedstock in chemical composition for the hydrogenation process;

- low productivity;

- None of the electrodes can be used as a manufacturer of atomic hydrogen.

The problem solved by the proposed utility model is the creation of a plant for processing raw materials, which allows to increase the productivity of the plant by producing atomic hydrogen and oxygen directly in the plant, while significantly simplifying the design of the plant itself.

The technical result in the proposed utility model is achieved by creating a plant for processing raw materials, including a feed hopper, a reaction chamber associated with a power source and with inlet and outlet nozzles, the reaction chamber being made in the form of a housing in which electrodes are installed, which, according to the utility model, is equipped with a device for collecting gaseous oxides and hydrides with a bubbler, and the loading hopper is equipped with an ultrasonic disperser, while the reaction chamber body is made in the form of a flat tank spine, in the lower part of which there is an electrode designed to accelerate the process of dissociation of water, and the upper part of the tank, which has a positron source on the inner surface, is used as the second electrode.

The use of an electrode designed to accelerate the process of dissociation of water from a composite material based on boron nitride (B ¹¹ N ¹⁵ ) reinforced with ultrafine silicon carbide SiC and carbon fiber allows the production of atomic hydrogen, which is necessary to improve the quality of raw materials.

The use of either Zn ⁶⁵ , or Mn ⁵⁴ or Fe ⁵⁵ as the source material of positrons makes it possible to weaken the CH bond in the feed to saturate it with atomic hydrogen.

The proposed design has a low energy intensity, because it is the galvanic electrolysis of water.

The design provides a safe environmental process, as through the use of a device for collecting gaseous oxides and hydrides, no hazardous emissions to the atmosphere occur.

The proposed design can be used for the production of hydrogen, acetylene, etc.

Easy replacement of the raw materials loaded into the hopper (crude oil, fuel oil, asphaltites, wastewater, environmentally hazardous liquid waste, etc.) expands the functionality of the proposed installation.

The proposed utility model allows adsorption of water from raw materials, for example, oil.

The conducted patent studies showed that technical solutions with the indicated set of essential features are not known in similar designs of installations for processing liquid or gaseous raw materials, i.e. the proposed solution meets the criterion of "novelty."

We believe that the information set forth in the application materials is sufficient for the practical implementation of the invention.

The proposed installation for processing raw materials is illustrated by the following description of the design and the drawing, which shows the layout of the installation equipment.

The installation for processing raw materials consists of a loading hopper 1, with an ultrasonic dispersant 2, a reaction chamber connected to a power source 3 and an input 4. and output 5 pipes, a device for collecting gaseous oxides and hydrides 6 with a barbator 7

The reaction chamber consists of a body in the form of a flat container 8, in the lower part of which an electrode 9 is placed, designed to accelerate the process of dissociation of water, and the upper 10 part on the inner surface has a material - a source of positrons 11.

The upper part of the container is used as the second electrode. As the source material of the positrons 11 can use either Zn ⁶⁵ , or ML ⁵⁴ or Fe ⁵⁵ .

In this case, the electrode 9, designed to accelerate the process of water dissociation, is made of a composite material based on boron nitride (B ¹¹ N ¹⁵ ) reinforced with ultrafine silicon carbide SiC and carbon fiber, the authors of which do not claim novelty, because He is known (see. See. Pol. Decision on z-ke No. 2006129186, С04В 35/00, 2006)

Consider the work of the proposed installation for processing raw materials, for example, the processing of heavy oil raw materials.

The loading hopper 1 is filled with oil, additionally water and alkali are introduced into it, then the ultrasonic dispersant 2 is turned on and the contents of the hopper are subjected to ultrasonic dispersion.

The volume of oil thus prepared is fed through the inlet pipe 4 into the reaction chamber.

The electrode 8, designed to accelerate the process of dissociation of water, is oleophilene and hydrophobic, that is, which means that it absorbs petroleum products in the first place and holds them, regardless of the medium in which it occurs (water, gas).

An alternating voltage is applied between the electrodes, namely, the electrode 8 and the second electrode 9, which causes microarc discharges in the micropores filled with water and alkali of the electrode 9, leading to the dissociation of water and the formation of atomic hydrogen and oxygen.

At the same time, the positrons are irradiated with oil located in the reaction chamber.

Depending on technological capabilities, either Zn ⁶⁵ , or Mn ⁵⁴ or Fe ⁵⁵ can be used as a material

This allows you to weaken the CH bond in oil to saturate it with atomic hydrogen.

The resulting atomic hydrogen and oxygen gasify the oil layer, which leads to the formation of hydrogen sulfide, sulfur dioxide, carbon oxides, which are passed through a bubbler 7 at the outlet of the reaction chamber and collected in a device for collecting gaseous oxides and hydrides 6.

Excess hydrogen in atomic form binds to excess carbon of oil, forming light hydrocarbons, clarifying oil, and increasing its volume.

Experimental tests of the proposed utility model were conducted.

Since the main source of hydrogen and oxygen in the proposed utility model is water, the first task was to make sure that the nanostructured electrode easily decomposes water due to microarc discharge in microvolumes of materials filled with water. Water with 1.5% alkali was poured into a glass vessel, and then an electrode and foil were placed in the vessel as the second electrode

The vessel was hermetically sealed, placed in a plastic bag and turned on the power.

After 30 minutes, oxygen accumulated inside the bag, and a torch of hydrogen was ignited outside the bag.

Having ascertained that the nanostructured electrode decomposes water, the experiment on the hydrogenation of fuel oil was continued.

Fuel oil was preliminarily saturated with alkaline water in an ultrasonic field, and fed into the reaction chamber by gravity.

Under the influence of electric voltage between the electrodes (the electrode and the body, which is the second electrode and the positron source), a microarc discharge arose and atomic hydrogen and oxygen formed.

Within 1-3 minutes, the fuel oil flowing through the reaction chamber was clarified.

The analysis of the obtained product showed that C5 diesel fuel with a low sulfur content is formed.

Gas analysis confirmed that the gaseous products were SO ₃ , H ₂ S, CO, CO ₂ .

The experiment was repeated several times, which led to a strong clarification of the product, sometimes reaching gas condensate according to the results of chemical analysis.

Claims (3)

1. Installation for processing raw materials, including a loading hopper, a reaction chamber associated with a power source and with inlet and outlet pipes, the reaction chamber is made in the form of a housing in which electrodes are installed, characterized in that it is equipped with a device for collecting gaseous oxides and hydrides with a bubbler, and the loading hopper is equipped with an ultrasonic disperser, while the reaction chamber body is made in the form of a flat container, in the lower part of which there is an electrode designed to accelerate ECCA dissociation of water, and the upper part of the vessel having the inner surface material - positron source, used as a second electrode. 2. Installation for processing according to claim 1, characterized in that the electrode designed to accelerate the process of dissociation of water is made of a composite material based on boron nitride (B ¹¹ N ¹⁵ ) reinforced with ultrafine silicon carbide SiC and carbon fiber. 3. Installation for processing according to claim 1, characterized in that as the source material of the positrons use either Zn ⁶⁵ , or Mn ⁵⁴ or Fe ⁵⁵ .