RU2506504C1 - Solar power plant for chemical reactions - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: invention refers to solar engineering and can be used for carrying out chemical reactions. A solar power plant for chemical reactions includes branch pipes and a heater. The plant includes a cubic working chamber with a transparent opening, inside which a porous body is located, which is supported on both sides with branch pipes in the form of tubes, an upper branch pipe for initial reagents, and around the lower branch pipe there located is a spiral-shaped heat exchanger that is connected to cooling agent supply and discharge tubes; besides, hot cooling agent discharge from the housing is performed, and to the chamber there additionally installed from above is a branch pipe for discharge of gaseous reaction products with the spiral-shaped heat exchanger.

EFFECT: possibility of carrying out reactions between different reagents and improving use efficiency of renewed energy sources at carrying out high-temperature reactions.

1 dwg

Description

The invention relates to solar technology, and can be used for chemical reactions.

A device for carrying out reactions [1] is known, which contains a cylindrical translucent photochemical reactor made in the form of a Dewar vessel made of Pyrex glass and having a selective reflective coating on the outer side of the concentrator side, a means of mechanical stirring of the reaction mass, made in the form of a water-cooled body with pipes and input the reaction mass and the selection of monomer, respectively, and located in the body formed by the pump cavity with a stirrer, and the stimulator of the photochemical reaction, Making a coil in the form of laid tube of glass type "Pyrex". The reactor outlet is hydraulically connected to the cavity at the mixer level, the pump to the inducer, the latter to the reactor inlet, and the coil tube has a selective absorbing coating on the side opposite to the incident solar radiation.

The disadvantage of this device is its complexity - they contain a large number of pipelines and mechanisms, which increases the cost and energy consumption, as well as the limited number of reactions.

The known catalytic helioreactor [2], which is a combination of a catalytic reactor and a radiant energy receiver, consists of a housing, a transparent window through which concentrated solar flux passes and heats the catalytic absorber, which consists of three layers (1), (2), (3 ), a pipe for entering the reactor of the initial reaction mixture, a mixer-heat exchanger or evaporator, a collector, an outlet pipe for the exit of reaction products.

The disadvantage of this helioreactor is the need: selection of the reaction mode - the feed rate of the starting materials; determining the optimal cell size of the absorber; determining the distance between the layers of the absorber; determination of thermal conductivity between the layers of absorbers. All this complicates the design and process of the reactions, and the absorber can be configured to carry out reactions between specific reagents. In addition, the gaps between the layers of the absorber reduce the efficiency of use of solar energy.

The closest in technical essence is a helioreactor [3], containing a housing with a preliminary chamber and a reaction chamber having a heater and nozzles and supply of reagents and removal of the target product, respectively. The solar reactor further comprises a hollow displacer piston installed in the housing, made of heat-insulating material and separating the housing into two cavities, which serve as preliminary and reaction chambers, and one of the end walls of the housing serves as a heater, and longitudinal grooves are made hydraulically connecting on the side surface of the displacer piston cameras. The heater has a concave outer surface facing the solar radiation concentrator.

The disadvantage of this helioreactor is its complexity with the inclusion of a displacing piston with thermal insulation and side grooves that hydraulically connect the two chambers, the inability to conduct solid-phase reactions and the reaction products can only be gases.

The objective of the invention is to simplify the device and expand the scope of its use for carrying out reactions between compounds in different phase states.

EFFECT: possibility of carrying out reactions between different reagents and increasing the efficiency of using renewable energy sources during high-temperature reactions.

The essence of the invention lies in the fact that the solar installation for chemical reactions includes nozzles, a heater, where the installation contains a cubic working chamber with a transparent window, inside of which there is a porous body supported on both sides by nozzles in the form of tubes, the upper nozzle for the starting reagents, and around the lower pipe is a spiral heat exchanger, which is connected to the pipes for supplying and discharging refrigerant, while the removal of hot refrigerant is carried out from the housing, and additionally to the chamber mounted an outlet for removing gaseous reaction products from the helical coil.

Figure 1 schematically shows a solar installation for chemical reactions.

The solar installation contains a concentrator 1, a cubic working chamber 2 with a transparent window 3, fixed to the housing 4 and with a porous body 5 located in it having the shape of a torus. A pipe 6 is connected to the chamber above, and a pipe 7 is connected below from the bottom to supply the starting materials and discharge the reaction products, respectively. The nozzles 6 and 7 are brought to the porous body 5 and hold it in the chamber. The device further comprises a pipe 8 for the removal of gaseous reaction products and heat exchangers 9 and 10 connected to the tubes for supplying 11 and removal of refrigerant (water) 12. The heat exchanger 9, in contrast to the heat exchanger 10, is partially located in the chamber and the removal of hot refrigerant (water) is carried out from the housing. As the porous body 5, graphite, platinum or other heat-resistant, inert material can be used.

Installation works as follows.

Solar radiation focused by the concentrator 1, passing through a transparent window 3 into the chamber 2, heats the porous body 5. Into the chamber 2 to the porous body 5 through the nozzle 6 enter solid in the form of powder or liquid source reagents. The porous body 5 has a high absorption coefficient of solar radiation. In a porous body, solid starting materials melt and high-temperature reactions proceed. To stop the reversible reactions and increase the yield of the target product, the reaction products immediately after leaving the porous body 5 enter the outlet pipes 7 and 8, where they are cooled by heat exchangers 9 and 10. Cooling in the heat exchangers occurs due to the refrigerant (water) supply and discharge through pipes 11 and 12, respectively.

In the installation, it is possible to carry out reactions between gaseous, liquid and solid reagents.

With gaseous starting materials, they are fed through the pipe 7, and the reaction products are discharged through the pipe 8, and the heat exchanger 10 works (the heat exchanger 9 is turned off).

With solid-phase starting materials, they are supplied through the nozzle 6 in the form of a powder to the porous body 5, passing through which, the starting materials are heated by solar energy and react. On the outlet pipe 7, where they are cooled, the reaction products are discharged, and the heat exchanger 9 works (the heat exchanger 10 is turned off).

If liquid, solid and gaseous products are formed during reactions between liquid or solid reagents, then liquid and solid products are discharged through pipe 7, and gaseous products are discharged through additional pipe 8, and both heat exchangers 9 and 10 work.

The advantage of the proposed solar installation in its simplification:

- due to the shape of the working chamber;

- the use of a porous body, instead of layers;

and efficiency:

- by expanding the scope (use) of the reaction between the single phase states of the reagents (solid - solid-solid - liquid, liquid - gaseous, etc.);

- increased output through the use of a heat exchanger in the housing;

- the focus of the concentrator makes it possible to raise the temperature to 900-1100 ° C.

Solar installation can be used as a thermochemical solar energy accumulator.

Literature

1. B.R. Korpev, O. Almobekov, O.A. Niyazov et al. “Device for carrying out reactions”, copyright certificate No. SU 1489294 A1, F24J 2/42, B01J 19/08, bull. No. 4319437 / 24-06, 10.21.87

2. V.I. Anikeev, A.S. Bobrin, V.A. Kirillov. Catalytic helioreactor. Patent No. 2030694, F24J 1/00, F24J 2/42, application No. 5023109/06, publ. 03/10/1995.

3. P.F. Rzayev, O.M. Salamov, S.Ya. Akhundov et al. Helioreactor, copyright certificate No. SU 1563332 A1, F24J 2/00, 2/42 bul. No. 4608206 / 24-06, 10.10.88

Claims (1)

Solar installation for chemical reactions, including nozzles, heater, characterized in that the installation contains a cubic working chamber with a transparent window, inside which there is a porous body supported on both sides by nozzles in the form of tubes, an upper nozzle for the starting reagents, and around the lower nozzle is arranged spiral a heat exchanger that is connected to the pipes for supplying and discharging refrigerant, while the removal of hot refrigerant is carried out from the housing, and an additional pipe for I withdraw the gaseous reaction products with a spiral heat exchanger.