FR3075330A1 - ENERGY PRODUCTION SYSTEM - Google Patents

Abstract

 The present invention relates to an energy production system comprising means for collecting solar energy and means for producing electricity, characterized in that the electricity generator comprises an absorber (5) receiving the energy. solar to heat an expansion gas, said absorber (5) being arranged in an optional heating zone by a burner (8).

Description

POWER GENERATION SYSTEM

Field of the invention

The present invention relates to the field of solar energy production from a Fresnel mirror concentrator system ensuring the heating of a heat transfer fluid at high temperatures, up to 500 ° or more than 700 ° C, in a thermal collection element having an absorbing tube placed at the focal point of the concentrator or of the series of concentrators.

D ¹ in general, a solar energy conversion device aims to provide a useful power in solar radiation 'that is to say transforming the energy comprises for this purpose an absorber, physical c having the function of converting captured. There an element

Incident solar electromagnetic energy into another useful form of usable energy (for example electrical energy in the case of a photovoltaic module or a thermoelectric module, thermal energy in the case of a heater -solar water, etc.). However, the useful power delivered by the device depends on several factors, including the efficiency of the conversion of the absorber, the surface of the absorber allocated to the capture of solar radiation (or "capture surface") and the power of incident solar radiation on the absorber. Since the efficiency of the conversion depends on the technology used to make the absorber, for a given technology, the useful power is therefore regulated by the area allocated to the capture and the power of the radiation.

In particular, when the area allocated to the collection of solar radiation is reduced, for example to limit the cost of the absorber, it is usual to concentrate the power of solar radiation on the absorber by means of a solar concentrator (for example a Cassegrain system, a parabolic mirror, a standard or linear Fresnel lens, a set of lenses, etc.). The solar concentrator is an optical system which focuses the solar radiation on a focal plane and the surface of collection of

The absorber, flat, coincides with the focal plane of the concentrator. The focusing of the radiation on the absorption surface of the absorber thus makes it possible to compensate for the small dimension thereof.

However, a solar energy conversion device based on a solar concentrator is sensitive to the angle of incidence of solar radiation, and this is all the more so when the absorption surface of the absorber is reduced. In fact, there is always an angle of incidence of the solar radiation, defined relative to the optical axis of the solar concentrator, beyond which the focusing is no longer carried out on the absorber itself.

In addition, the incidence of the sun varies throughout the day, which is why the concentration solar conversion systems are motorized (eg using a tracker) to follow the progress of the sun in the sky, in order to guarantee a normal incidence of solar radiation. This type of system, however, requires very precise sun tracking, a slight angular offset (e.g. 0.1 °) relative to the sun directly resulting in a significant drop in device performance.

State of the art

The international patent application WO 2005090873 describing a solar sensor which comprises a reflector of the linear concentrator type and an absorber spaced from the reflector are known in the prior art. The absorber includes a first absorber element spaced from the reflector, which has a surface oriented in the direction of the reflector to receive solar radiation from the latter as well as a conduit transporting a fluid thermally coupled to the surface of the absorber. The absorber also includes a second absorbing element having an absorbing surface oriented to receive the directly transmitted solar radiation, and a conduit transporting a fluid coupled at the thermal level to the absorbing surface of the second absorbing element.

Also known is European patent application EP 3136018 concerning a solar energy conversion system comprising:

- a solar concentrator provided with an optical axis and able to focus incident solar radiation on a focal plane;

- a frusto-conical mirror comprising a large base and a small base, in which the small base is coincident with the focal plane of the solar concentrator, the top of the frusto-conical mirror is arranged on the optical axis of the solar concentrator and the large base is disposed between the small base and the concentrator, so that the solar concentrator and the frustoconical mirror together define a secondary focal surface comprising a portion inscribed in the small base of the frustoconical mirror and a frustoconical portion inscribed in the volume delimited by the frustoconical mirror; and a solar absorber at least partially inscribing the small base of the frustoconical mirror;

The solar absorber further comprises a portion registering the intersection of the frustoconical portion of the secondary focal surface with a plane containing the optical axis of the solar concentrator.

Another solution is described in patent application WO2006027438 concerning a device for producing hydrogen using low energy solar energy using solar collectors operating during the day to produce a hot fluid, and heat sinks operating at night for produce a cold fluid, the hot fluid and the cold fluid are stored in separate tanks to have permanently a hot source and a cold source, the solar collectors work in closed circuit with the hot fluid storage tank with a volume of fluid constant, the heat sinks operate in a closed circuit with the cold fluid storage tank with a constant volume of fluid, a closed secondary circuit containing a working fluid is used in a Rankine cycle.

Disadvantages of the prior art

The disadvantage of the solutions of the prior art is that in the absence of sunshine or cloud cover, the level of energy production decreases considerably and no longer provides the expected energy. These installations therefore require association with other installations or access to an independent electrical network to compensate for the random breaks in production specific to solar power plants.

Furthermore, in the solution described in patent application WO2006027438, significant losses occur in the primary and secondary working fluid circuits.

Solution provided by the invention

In order to remedy these drawbacks, the present invention relates to an energy production system comprising means for collecting solar energy and means for producing electricity, characterized in that the electricity generator comprises an absorber receiving the solar energy for heating an expansion gas, said absorber being arranged in an optional heating zone by a burner.

Advantageously, the system according to the invention has all or some of the following characteristics:

- It further comprises hydrolysis means.

the electricity production means are arranged to receive thermal energy resulting from the recombination of the hydrolysis products in the absence of solar energy.

- the gas in the expansion machine is placed in the focus of a concentrator.

it further comprises means for supplying the means of electrical production by an additional energy source in a reversible manner.

Detailed description of a nonlimiting example of the invention

The present invention will be better understood on reading the detailed description of a nonlimiting example of the invention which follows, referring to the accompanying drawings in which:

- Figure 1 shows a schematic view of a first embodiment of the invention

- Figure 2 shows a schematic view of a second embodiment.

Schematic description of the invention

Figure 1 shows a schematic view of a first embodiment

The installation comprises a solar concentration system illustrated diagrammatically in the example described by a flat collector (1) forming a diffraction grating of the Fresnel collector type returning the solar radiation to a hemispherical concentrator (2) mounted on an orientable structure. to focus the radiation a circular point

located at level of a equipment of capture formed by a pregnant (3) vacuum opening through a quartz window (4). The enclosure (3) under empty defines a cavity

absorbent limiting losses by air diffusion. The quartz window (4) is covered with an anti-reflection coating in the adequate spectrum to avoid more than 30% of optical / thermal losses. General thermal insulation can be obtained, for example, with aerogels, expanded perlite, or even certain forms of carbon / graphite with excellent insulating properties and low cost since they are abundant and recycled materials.

The enclosure (3) contains an absorber (5) made of carbon / graphite and tungsten dendrites in a crystalline form absorbing 98% of the infrared radiation and at a melting point above 3.400 ° C.

The agglomeration of tungsten dendrites on carbon / graphite is carried out in a thin layer and under high temperature, forming a resistant carbide. The surface of the absorber (5) has microcavities made during molding, to approach the characteristics of a black body.

The enclosure (3) has several interfaces with conduits (6 to 9):

a duct (6) for the outlet of hot air adjustable in temperature for heating, cooking, and all metallurgy or industrial chemistry operations. This duct (6) allows controlled transfer to additional equipment for the use of hot air, and also makes it possible to reduce the pressure inside the enclosure (3)

- a conduit (7) for injecting a water mist which will be subjected to a temperature of 2,500 ° C, causing its spontaneous chemical dissociation into its two elements, H2 and O by cracking or thermolysis of 1 ¹ water allowing 1 ¹ obtaining hydrogen and oxygen, by dissociating by heat the atoms composing the H2O water molecule. This thermochemical reaction begins at high temperature (between 850 ° C and 900 ° C) and becomes complete around 2,500 ° C.

- A conduit (7) for extracting a jet of molecules of different masses then separated by means of a cyclonic vortex-type device generating two distinct flows of hydrogen and oxygen.

- a conduit (8) for the supply of a burner ΗΗ0 previously stored. This burner provides an energy contribution to generate a flame at around 2,400 ° C allowing to operate our system at night or in overcast skies.

The absorber device is modular, thus allowing the use of external heat when for example the HHO tank is found to be empty.

Description of a second embodiment

FIG. 2 represents a schematic view of a second exemplary embodiment.

It includes, as in the previous example, an enclosure with controlled atmosphere (3) opening through a quartz window (4) and containing an absorber (5). This absorber (5) produces a high temperature for the thermolysis of water introduced into the enclosure (3) by misting. It is also thermally coupled to an energy transformer (10). This energy transformer (10) can be constituted by a Whispergen gas boiler producing electricity (1KW) in cogeneration associated with a Stirling liquefaction device (or other) making it possible to liquefy the gases produced (H2 / HHO,) for storage, then a Stirling refrigeration unit (or other) for the production of cold working in cogeneration with the inevitable losses of the liquefier.

A liquefied H2 storage tank provides an energy carrier during the night or unfavorable weather conditions, for reinjection via a burner. The separation of the gaseous components obtained by thermolysis is ensured by a cell separating the gases resulting from thermolysis, and which can be indifferently a supersonic vortex, an HT electrolysis, a proton membrane, etc.

The absorber (5) is produced, for example, by isostatic pressing from very low cost carbon / graphite compounds, covered with a layer of suitable carbide such as silicon or tungsten, combined by surface sintering in successive thin layers.

In the example illustrated in FIG. 2, the absorber (5) is thermally coupled to an electricity generator (10) constituted by a confinement enclosure (11) thermally insulated inside which is positioned a high cylinder. coaxial pressure (12). This high pressure cylinder (12) is also thermally insulated.

Inside this high pressure cylinder (12) moves a high pressure piston (13) which ensures the cyclic compression of a gas actuating a second stage comprising a low pressure piston (14).

Air or water exchangers (15, 16) surround the confinement enclosures (11) and electric coils (17).

The pistons (13, 14) have a concave shape to receive and channel the flow in its center and limit losses and improve mechanical balancing.

The convex shape on one side (18) of the absorber (5) allows better distribution of the pressure stresses, while the other side (19), concave, allows it to collect and trap light as well as possible. whatever the angle of incidence, its surface being further surmounted by mini reliefs allowing better light trapping and increasing exchanges.

The general composition in the form of cylinders nested one inside the other allows the optimization of the surfaces and volumes, while minimizing the pressure losses. On the other hand, this type of arrangement allows easy manufacture but also assembly. Seals between segments can be achieved by high-performance graphite seals for high temperature ranges and at very low cost.

A possible larger additional stage could be used with more conventional materials such as aluminum, PTFE, steels, cast iron, etc.

The insulation is carried out by "smoke black", resulting from incomplete combustion, and having good insulating powers.

The device benefits from a continuously adjustable feedback via the electric generator which advantageously replaces the mechanical spring or the connecting rod with the f.c.e.m (force against electromotive). Thus, by varying the electrical parameters there is an adjustable stroke making operation in resonance mode possible.

Furthermore, the electromagnetic servo control of the pistons could allow easier starting by acting on them and initiating the starting process.

This type of motor is reversible to produce cold, or heat. This configuration is possible using the linear electric generator as a motor via the control electronics.

The sealed connection (20) for transmitting the mechanical work to the outside of the transformer enclosure can be constituted for example from carbon reinforced graphite rings, with several stages if necessary, the whole being contained in a pressurized bellows or membrane type.

pregnant

Claims (5)

Claims 1 - Energy production system comprising means for collecting solar energy and means for producing electricity, characterized in that the electricity generator comprises an absorber (5) receiving solar energy to heat a gas expansion, said absorber (5) being disposed in a heating zone comprising a burner (8). 2 - Energy production system according to claim 1 characterized in that it further comprises hydrolysis means. 3 - Energy production system according to claim 2 characterized in that the electricity production means are arranged to receive thermal energy resulting from the recombination of hydrolysis products in the absence of solar energy. 4 - Energy production system according to claim 1 characterized in that the gas in the expansion machine (10) is placed in the focus of a concentrator (19). 5 - Energy production system according to claim 1 characterized in that it further comprises means for supplying the electrical production means by an additional energy source.