JPH01296052A - Solar chimney - Google Patents

Abstract

PURPOSE:To reduce markedly the material cost for a tube, by providing a transparent sheet having a hole in a central part thereof, a cylindrical tube formed of a foldable material and jointed to an upper part of the hole, and a net having ventilation resistance for causing the tube to self-support. CONSTITUTION:A tube 2 is formed of a foldable material, e.g., a polyvinyl chloride sheet or a polyethylene sheet. The tube 2 is caused to self-support by the air resistance of natural convection to a net 5 disposed in the tube 2. The mesh size of the net 5 is determined taking into account the weight of the tube 2 itself, the height of the tube 2, an average wind speed or the like. A transparent sheet 1 is supported by a multiplicity of struts 3. An operation of lowering (folding) the tube 2 is controlled by a controlling rope 6. This construction realizes a reduction in the cost of the tube 2, which constitutes a major cost factor.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a solar chimney that is applied to solar thermal power generation, seawater desalination, air drying systems, etc. that generate electricity using solar thermal energy.

[Conventional technology]

As shown in Figure 7, a solar chimney is a system that heats the ground beneath a transparent sheet 1 using solar heat, induces natural convection, and exhausts the warmed air through a cylinder 2 that acts as a chimney in the center. It is a system that Applications include power generation systems that utilize natural convection, water distillation systems that utilize the condensation of humid air within the tube 2, and drying systems that dry objects under the transparent sheet 1. Note that 3 indicates a support column and 4 indicates the ground surface.

(Problems to be Solved by the Invention) The power generation efficiency of solar chimney power generation is theoretically proportional to the height of the cylinder 2, and under ideal conditions, the efficiency is 1% at a height of 300 m. This extremely low efficiency requires that the entire system be constructed at a very low cost.

The distillation/drying system also has a small temperature difference with the outside air, so it has low efficiency and needs to be constructed at low cost.

Since the transparent sheet 1 occupies most of the installation area, it is essentially a low-cost system, but there are three major cost problems:

(1) The biggest problem is the installation cost of tube 2. The height of the cylinder 2 must be at least 100 m, and for power generation it is preferably about 1000 m. The biggest challenge is how to install such a high-rise chimney at a low cost.

(2) Although it is necessary to hold the transparent sheet 1 on the ground surface 4 via an air layer, this support mechanism for the transparent sheet 1 is also a big problem in terms of cost reduction. Up until now, a method of supporting the transparent sheet 1 using a large number of support pillars 3 has been used, but this method not only increases the cost but also creates dents in the transparent sheet 1.
Another problem has been that rainwater collects in the depressions and needs to be drained.

(3) Since it is essentially a low-efficiency system, it is necessary to increase the area, but it cannot be located in areas where land costs are high. Therefore, it becomes necessary to either locate on land where effective land use is impossible, such as in desert areas, or to use the same land in combination with other uses.

In order to construct a high-rise chimney as a permanent facility, it is necessary to have sufficient wind resistance, which requires a huge amount of money in terms of construction materials and construction costs. Regarding the installation of the transparent sheet 1, it is not easy to install it at low cost with a structure that has wind resistance and can drain water.

This invention has been made to solve the above problems. In other words, since solar thermal energy systems basically operate during the daytime on a sunny day, they do not necessarily need to be a permanent structure, but only need to be a structure that functions only under conditions that allow operation. If you can take a sheltered position during strong winds, it will be easier to ensure wind resistance.

In this invention, from the above-mentioned viewpoint, the above-mentioned problems are solved by a method in which the solar chimney is constructed by making the simple and transparent sheets stand up on their own using natural convection or stand upright by means of standing upright only when it is possible to operate. The purpose is to

[Means to solve the problem]

In this invention, a transparent sheet with a hole in the center is placed on the ground or water surface, a cylindrical tube made of a collapsible material is bonded to the top of the hole, and a transparent sheet is installed inside or at the upper end of the transparent sheet. It is equipped with a membrane or mesh that has ventilation resistance to make the cylinder self-supporting.

Further, in order to make the part stand upright, a means for making it stand upright can be provided at the tip of the part.

[Effect]

In this invention, the transparent sheet of the cylinder is made to stand on its own by natural convection when it is operational, and the tray and the transparent sheet are retracted above the ground surface during strong winds.

Furthermore, the transparent sheet is highest at the center at the bottom of the chimney, and is lower at the periphery, preventing rainwater from collecting on the transparent sheet.

Further, the tube is made to stand upright using a means for standing it upright, and the tube acts as a chimney.

〔Example〕

Hereinafter, the present invention will be described in detail based on the drawings.

FIG. 1 shows an embodiment of the present invention. Reference numeral 1 is a transparent sheet, and a cylinder 2 that acts as a chimney is provided in the center. 3 are support columns, which are installed on the ground surface 4. Item 2 is made of a foldable material, such as a vinyl chloride sheet or a polyethylene sheet. 5 is a net provided at the upper end and/or the center of the tube 2, and 6 is a control lobe. This method uses the air resistance of natural convection against the net 5 installed inside the tube 2 to make the tube 2 self-supporting. The size of the mesh of the net 5 is determined by taking into account the weight of the tube 2, its height, average wind speed, etc. The transparent sheet 1 is supported by a large number of support columns 3. In this embodiment, the periphery of the transparent sheet 1 is open, and in order to take in outside air and induce natural convection, it is first necessary to make the cylinder 2 independent. It is possible to use the following. Lower (fold) tube 2 W
Control of A uses a control lobe 6. This embodiment realizes a reduction in the cost of the tube 2, which is the main cost factor of the solar chimney.

FIG. 2 is a diagram showing another embodiment of the invention. This is a system in which the cylinder 2 and transparent sheet 1 are made to stand on their own through natural convection.

Only the peripheral portion of the transparent sheet 1 is supported and fixed by support columns 3 at intervals. The rest is the same as the embodiment shown in FIG. This example is shown in Clause 2. This greatly reduces the construction cost of the transparent sheet 1. Since the number of support columns 3 is greatly reduced compared to the embodiment shown in FIG. 1, installation on the water surface becomes easier and restrictions on land costs are eliminated. Furthermore, since the transparent sheet 1 has a structure in which the central part of the lower part of the cylinder 2 is highest and the peripheral part is lower, rainwater does not accumulate in the transparent sheet 1, and no measures for draining water are required.

FIGS. 3(a) and 3(b) are a sectional view and a perspective view showing still another embodiment of the present invention. In the embodiment of FIG. 2,
Since tension is applied directly to the transparent sheet 1 when the tube 2 is made to stand on its own, it is necessary to maintain sufficient tensile strength of the transparent sheet 1, but this may result in high material costs for the transparent sheet 1. There is. This also applies to the material strength of the cylinder 2. Therefore, in the embodiment shown in FIG. 3, a plurality of support lobes 7 are connected to the upper part of the tube 2, passed through the inside of the tube 2 and under the transparent sheet 1, and then the other end of the support lobes 7 is connected to the transparent sheet 1. It is fixed to the ground surface 4 at the periphery. A reinforcing ring 8 is installed at the joint between the tube 2 and the transparent sheet 1 for strength reinforcement. By connecting the tube 2 and the transparent sheet 1 to the support lobes 7 at appropriate intervals, it is possible to prevent tension from being applied directly to the tube 2 and the transparent sheet 1 when the tube 2 is made to stand on its own.

In addition, when reinforcing only the material strength of the transparent sheet 1, the support lobe 7 may be connected to the lower part of the tube 2.

FIG. 4 shows still another embodiment of the present invention, 9
is a means for standing upright, and is attached to the upper end of the tube 2, such as a hot air balloon or a balloon filled with a lightweight gas such as helium gas or hydrogen gas (hereinafter simply referred to as a balloon). The size of the balloon 9 is determined by taking into account the weight of the tube 2, its height, average wind speed, etc. The rest is the same as the embodiment shown in FIG.

In addition, the balloon 9 may be attached to the embodiments shown in FIGS. 2 and 3, and the structure may be configured as shown in FIGS. 5 and 6.

In the above, a case has been described in which a balloon 9 filled with lightweight gas is used as a means for lifting the tube 2. However, other means include the use of a hot air balloon, a remote control helicopter, or a propeller with an engine directly lifting the tube 2. It is possible to construct a solar chimney by installing it on top of a solar chimney. In this case, fuel is required, but once natural convection has been induced, the airflow ejected from the top of the chimney acts to push the hot air balloon or propeller up, so the amount of fuel needed to maintain the attitude is considerably reduced. .

In the case of power generation in the above embodiment, an air turbine and a generator are installed directly below the cylinder 2. In the case of distillation (seawater desalination), seawater is introduced under the transparent sheet 1, where it is evaporated and condensed in the tube 2 to produce distilled water, which is allowed to fall along the inner wall of the tube 2 and collected. In the case of drying, the object is placed under the transparent sheet 1, dried under direct sunlight, and the released water vapor is discharged from the cylinder 2 by natural convection.

(Effects of the Invention) As described in detail above, the present invention has a cylindrical sheet made of a transparent sheet with a hole in the center and a foldable material bonded to the top of the hole, which is laid on the ground or water surface. Since it is equipped with a tube and a membrane or net installed inside or at the upper end of the tube that is breathable and has ventilation resistance to make this section independent, (1) Material costs and construction costs for the tube and transparent sheet. can be significantly reduced.

(2) There is no need to drain rainwater accumulated on the transparent sheet.

(3) It becomes easy to install on water surfaces such as sea level or lake level, and restrictions on land costs are eliminated.

This effect can be obtained. This invention makes it possible to construct solar chimneys at low cost, and it is possible to produce a great energy saving effect.

Furthermore, when this invention is installed above seawater, the water vapor that evaporates under the transparent sheet condenses inside the chimney, and by collecting this, it is possible to construct a very simple seawater desalination system. It is.

Furthermore, a device in which the cylinder is made to stand upright using an upright means can be operated more reliably than one in which the tube is made to stand upright using a self-cutting blade.

[Brief explanation of the drawing]

FIG. 7 is a cross-sectional view schematically showing the structure of a conventional solar chimney. In the figure, 1 is a transparent sheet, 2 is a tube, 3 is a support column, 4 is the ground surface, 5 is a net, 6 is a control lobe, 7 is a support rod 111, 2, 3, 4, 9: claw Ring Figure 5 Figure 6

Claims (2)

[Claims] (1) A transparent sheet with a hole in the center to be laid on the ground or water surface, a cylindrical tube made of a collapsible material bonded to the top of the hole, and a transparent sheet placed inside or at the top of the tube. A solar chimney characterized by having a membrane or a mesh having air permeability and air resistance to make the chimney self-supporting. (2) A transparent sheet with a hole in the center to be laid on the ground or water surface, a cylindrical tube made of a collapsible material bonded to the top of the hole, and a A solar chimney characterized by comprising means for making the tube stand upright.