KR101159439B1 - Absorber of solar radiation - Google Patents

Abstract

The present invention, a reflector for concentrating and supplying the incident solar radiation energy, and receives the solar radiation energy supplied from the reflector, one side is formed with a heat resistant glass window and an inlet for introducing a working fluid, the other side is solar radiation A housing formed with an outlet for drawing out the working fluid heated by energy, and provided inside the housing, generating hydrogen from the working fluid using the incoming solar radiation energy, and having different porosities depending on the concentric diameter. In the solar radiation absorber comprising a hydrogen generating portion made of a porous material, the porous material of the hydrogen generating portion is formed by cutting a plurality of porous materials having different porosities, respectively, into a plurality of ring shapes, and then a plurality of rings at the central portion. Porosity is densely stacked in steps toward the outside Then provides the absorber of solar radiation, it characterized in that the fastening.
Therefore, in the absorber of the solar radiation energy, the flow rate of the working fluid can be supplied in accordance with the amount of the flow rate of the solar radiation energy introduced by the hydrogen generator, and it is possible to concentrate the flow rate of the working fluid in the center, It is possible to suppress the breakdown and melting of the material center due to thermal stress.

Description

ABSORBER OF SOLAR RADIATION

The present invention relates to an absorber for solar radiation energy, comprising a hydrogen generating unit in which a porous material having a different porosity is laminated stepwise in a housing of the absorber, thereby preventing the center of the porous material constituting the hydrogen generating unit from being deformed and broken. Relates to an absorber of solar radiation.

In general, a central solar receiver includes a means for circulating a working fluid in direct and indirect heat exchange relationship between the solar absorber and the solar absorber, the solar receiver absorbing concentrated sunlight at a high temperature, typically from 700 to 1500 ° C. The heat generated by the solar absorber in the solar receiver serves as a heat carrier fluid or delivers a working fluid adapted to perform a thermochemical process.

In known central solar receivers called so-called tubular receivers, the working fluid usually flows inside the tube located proximate to the inner periphery of the solar receiver housing.

In such a receiver, solar radiation is absorbed at the outer surface of the tube and transferred to the working fluid as heat, thereby heating the working fluid.

The overall heat transfer resistance of the tubular central solar receiver and the resulting heat loss are relatively large.

In view of this drawback of the tubular central solar receiver, a central solar receiver with a volumetric solar absorber has been proposed, and the central solar receiver in the form of a volumetric solar absorber is about 5 to 10 times the solar radiation of the conventional tubular receiver. It is suggested that it is possible to handle fluxes and that the size and weight of the receiver can be reduced accordingly.

Figure 1 shows a central solar receiver with a conventional volumetric solar absorber of the typical prior art.

The receiver has a housing 1 provided with a window 2 having heat resistance while being able to receive solar radiation concentrated in an elliptical reflector.

The rear wall 3 incorporated into the frame 4 divides the internal space of the housing 1 into a central portion 5 and a peripheral edge 6.

The frame 4 holds a volumetric solar heat absorber 7 composed of a plurality of parallel steel meshes.

The receiver further comprises a suction tube 8 for entering the working fluid, for example ambient air, and an opening 9 for the outlet of the heated working fluid.

The suction tube 8 and the opening 9 can be connected by suitable duct means, the working fluid entering through the suction tube 8 flows through the periphery 6 of the housing 1 and is concentrated upon incidence. It is redirected by the window 2 to flow across the volumetric solar absorber 7 in essentially the same direction as the solar radiation.

However, the conventional solar radiation absorber has a problem that the high temperature is concentrated only in the center of the porous material, the solar heat flux flowing into the front portion is unevenly distributed.

In addition, the permeability of the fluid flowing into the center of the porous material is reduced, there is a problem that the use of the center of the inlet flow rate is smaller than the edge is inefficient.

In addition, since the flow rate of the fluid passing through the central portion where the high temperature is concentrated has a problem that the porous material is broken.

It is an object of the present invention to provide an absorber of solar radiation with a change in pore size so that the mass flow rate of the fluid passing through the porous material can be uniformly supplied in accordance with the amount of the incoming solar heat flux.

It is another object of the present invention to provide an absorber of solar radiation energy in which a porous material is stacked in a step so that the center of the porous material is broken and melted due to thermal stress.

The present invention, a reflector for concentrating and supplying the incident solar radiation energy, and receives the solar radiation energy supplied from the reflector, one side is formed with a heat resistant glass window and an inlet for introducing a working fluid, the other side is solar radiation A housing formed with an outlet for drawing out the working fluid heated by energy, and provided inside the housing, generating hydrogen from the working fluid using the incoming solar radiation energy, and having different porosities depending on the concentric diameter. In the solar radiation absorber comprising a hydrogen generating portion made of a porous material, the porous material of the hydrogen generating portion is formed by cutting a plurality of porous materials having different porosities, respectively, into a plurality of ring shapes, and then a plurality of rings at the central portion. Porosity is densely stacked in steps toward the outside Then provides the absorber of solar radiation, it characterized in that the fastening.

In the present invention, the hydrogen generator of the solar radiation absorber provides a solar radiation absorber having a structure in which the porosity is reduced in proportion to the distance from the center.

The absorber of solar radiation energy according to the present invention has the following effects.

First, since the flow rate of the working fluid passing through the hydrogen generating unit, which is a porous material, can be uniformly supplied according to the flow rate of the incoming solar radiation energy, efficient operation can be achieved.

Secondly, it is possible to concentrate the flow rate of the working fluid to the center of the hydrogen generator by increasing the flow resistance at the edge of the hydrogen generator having a relatively high porosity.

Third, since the fluid is concentrated in the center of the porous material forming a high temperature material temperature, it is possible to suppress the breakage and melting of the porous material center due to thermal stress.

Fourth, it is possible to manufacture through the cutting process of the existing merchandise is easy to manufacture and mass production is possible.

1 is a diagram schematically showing the configuration of a prior art central solar receiver with a volumetric solar absorber.
2 is a view schematically showing the configuration of the solar radiation absorber of the present invention.
3 is an enlarged view of a hydrogen generator provided inside a housing of the solar radiation absorber of the present invention.
4 is a view illustrating a state of the hydrogen generating unit of FIG. 3 viewed from the side.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 2 is a view schematically showing a configuration of a solar radiation energy absorber according to the present invention, and FIG. 3 is an enlarged view of a hydrogen generator provided in the housing of FIG. 2, and FIG. 4 is a side view of the hydrogen generator of FIG. 3. Figure showing a state viewed from.

2 to 4, the absorber of the present invention includes a reflector 10 that concentrates and supplies incident solar radiation energy, and receives solar radiation energy supplied from the reflector 10, and one side thereof. The housing 20 is formed with a glass window 22 having heat resistance and an inlet 24 for introducing a working fluid, and an outlet 26 for drawing out a working fluid heated by solar radiation on the other side, and It is provided inside the housing 20, and generates hydrogen from the working fluid using the incoming solar radiation energy, and includes a hydrogen generating portion 30 made of a porous material having a different porosity depending on the diameter to the concentric.

Here, the absorber of solar radiation refers to an object or structure that can absorb incident solar radiation and convert it into heat.

The reflector 10 serves to concentrate incident solar radiation to the glass window 22 formed on one side of the housing 20, and a plurality of mirrors 12 are installed on the surface thereof, It is designed to focus on the focal zone 14 located on the central axis.

As the glass window 22 provided on one side of the housing 20, quartz having heat resistance is mainly used, and serves to supply the solar radiation energy concentrated in the reflector 10 to the interior of the housing 20. do.

The housing 20 has a cylindrical shape, one side of which is provided with an inlet 24 for introducing a working fluid, and the other side of the housing 20 is heated by the solar generator and the hydrogen generator 30 provided inside the housing. An outlet 26 through which the fluid is drawn out is formed.

Here, CH₄ + CO₂ is mainly used as the working fluid flowing into the inlet 24 of the housing 20.

The reaction formula of the reaction fluid CH₄ + CO₂ is as follows.

Scheme) CH₄ + CO₂ → 2CO + 2H₂

Carbon monoxide and hydrogen are generated as in the reaction scheme.

The amount of heat is increased by about 28% through the reaction of methane and carbon dioxide, and the generated synthesis gas is used for hydrogen production through a small process, a separation process, and the like.

The inside of the housing 20 is provided with a hydrogen generating unit 30 to cause a chemical reaction with the solar radiation energy supplied into the housing 20 through the glass window 22 to increase the temperature of the working fluid.

The hydrogen generating unit 30 is made of a porous material, serves to increase the heat transfer area, and generates hydrogen through a chemical reaction of the working fluid CH₄ + CO₂ and solar radiation energy.

It is preferable that a porous material constituting the hydrogen generator 30 is made of a material having a large specific heat.

In the case of solar energy, the chemical reaction is irregular due to the change of solar radiation over time (for example, decrease in solar radiation due to clouds), and at this time, the hydrogen generating part has heat storage capability when a material having a large specific heat is used. To store the heat in the hydrogen generating unit 30 even when the cloud is to continue to react.

The hydrogen generator 30 is formed to reduce the porosity in proportion to the distance from the center, and is designed to flow a lot of working fluid to the center of the housing 20 having a wide porosity.

In addition, the hydrogen generator 30 is formed of a plurality of rings having different porosities.

This is because the body of the housing 20 in which the hydrogen generator 30 is formed of a porous material is cylindrical, and the hydrogen generator 30 is installed to be inscribed inside the body of the housing.

The hydrogen generating unit 30 is formed by being stacked in a stepped shape corresponding to the center of the body of the housing.

This is because the working fluid flowing through the inlet 24 of the housing 20 rises due to the solar radiation energy flowing from the windshield 22 provided in the front of the housing 20, and the temperature of the working fluid rises. The heat flux forms a Gaussian distribution around the central portion of the hydrogen generator 30. The Gaussian distribution is such that the temperature of the central portion rises above the outside temperature, and the hydrogen generation portion having a relatively high porosity. The flow resistance of the edge portion 30 is increased, so that the flow rate of the working fluid is concentrated in the center of the hydrogen generator 30.

The absorber of the solar radiation energy configured as described above is formed so that the porosity of the hydrogen generator 30 made of the porous material provided in the housing 20 is different depending on the diameter up to the concentricity, and the porosity is proportional to the distance from the center. Is formed to be reduced, and by stacking in a stepped shape, the mass flow rate of the working fluid passing through the hydrogen generating unit 30 can be uniformly supplied according to the amount of the solar radiation energy flow rate introduced therein, and the porosity is relatively dense. Increased flow resistance of the edge portion of the porous material, so that it is possible to concentrate the flow rate of the working fluid to the center of the hydrogen generating portion, the center of the porous material of the hydrogen generating portion 30 due to thermal stress breakage and melting Can be suppressed and can be manufactured by cutting existing merchandise. And it would have to enable the production of a product without additional investment.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible.

Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: reflector 12: mirror
14: focus zone 20: housing
22: glass window 24: inlet
26: outlet 30: hydrogen generating unit

Claims (4)

A reflector that concentrates and supplies incident solar radiation,
A housing accommodating solar radiation energy supplied from the reflector, one side of which has a heat resistant glass window and an inlet for introducing a working fluid, and the other side of which has an outlet for drawing out a working fluid heated by solar radiation energy;
In the absorber of the solar radiation energy provided in the housing, generating hydrogen from the working fluid using the incoming solar radiation energy, comprising a hydrogen generating portion made of a porous material having a different porosity depending on the diameter to the concentric,
The porous material of the hydrogen generating unit is formed by cutting a plurality of porous materials having different porosities, respectively, into a plurality of ring shapes, and then fastening the plurality of rings by densely stacking the pores in a step form from the center to the outside. Absorber of solar radiation.
The method according to claim 1,
The hydrogen generator is a solar radiation absorber of the porosity is reduced in proportion to the distance from the center.
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