JPS6026245A - Solar heat collector - Google Patents

Abstract

PURPOSE:To prevent a convection flow of fluid caused by a contact between the air in the pipe and the surrounding atmosphere and further to prevent a damage of the pipe by a method wherein convection flow preventive plates are arranged in the inner glass pipe and a plurality of convection flow preventive plates are fixed by the holding means, both open ends of the vacuum glass pipe and their surroundings are closed by the thermal insulators. CONSTITUTION:Interior of the inner glass pipe 13 is divided into a plurality of sections by convection flow preventive plates 15 of silicone rubber which are arranged in a vacuum glass pipe and the opening part is closed by a hot thermal insulator 16, so that a convection between the air in the pipe and the surrounding atmosphere is prevented. At the same time a water conducting pipe 5 is held by the convection flow preventive plates 15, so that the damage of the glass pipe caused by vibration during transportation may be prevented. Due to no provision of aluminum fins, the cost can be reduced. A plurality of vacuum glass pipes are fixed with one holding means to make a block form, thereby their assembly becomes easy and no direct contact of metal to the vacuum glass pipe, resulting in reducing dispersion of heat caused by heat conduction.

Description

DETAILED DESCRIPTION OF THE INVENTION (1) Technical Field of the Invention The present invention relates to improvements in solar collectors that convert solar radiant energy into thermal energy using vacuum glass tubes.

(2) Background of the technology Currently, solar energy is being actively used for room heating, hot water supply for baths, kitchens, etc.

An example of how such solar energy can be utilized is realized by a system in which an energy conversion device called a solar collector is connected with a device such as a heat exchanger for heating or a hot water storage tank for storing hot water through piping. In such systems, a solar collector is a device that uses radiant energy from the sun to heat the heat medium circulating in the pipes to a high temperature exceeding about 60°C.

The structure of a solar collector consists of many double-walled glass tube assemblies consisting of an inner glass tube with a water conduit inside that circulates the heat medium, and an outer glass tube outside the inner glass tube. A vacuum is maintained between the outer and inner glass tubes forming a double structure, and the surface of the inner glass tube is coated with a selective absorption pattern to improve the absorption efficiency of solar energy. The second direction is planned. In the following, the double-structured glass tube assembly will be referred to as a vacuum glass tube.

(3) Prior Art and Problems Figure 1 is an exploded perspective view of a conventional vacuum glass tube 1, with a part cut away. The surface of the inner glass tube 2 is coated with a selective absorption film (not shown). Further, a hatched area 7, which is an open end between the inner glass tube 2 and the outer glass tube 3, is sealed with glass, and the inside is kept in a vacuum. code 4
is an aluminum fin with a semicircular cross section with a concave center part, and two aluminum fins 4 facing each other to form a cylinder are placed between the U-shaped water pipes 5 as shown in the figure. The structure is inserted into the inner glass tube 2 of the vacuum glass tube 1 as shown by arrow a. In one specific example, the length of the vacuum glass tube is about 1.4 m, and the inner diameter of the inner glass tube 2 is about 2.0 m.
It is 7cm.

In the vacuum glass tube having such a configuration, sunlight passes through the outer glass tube 3 and the cylindrical glass tube 2 coated with a selective absorption film, is supplied from the air temperature 6a in the inner glass tube 2, and is supplied to the water pipe 5. After being circulated, it enters another ladder pipe 6b and is sent to a heat exchanger or the like.

By the way, the above-mentioned vacuum glass tube is used with no heat insulating material placed on the insertion side of the water conduit 5 and left open, so air convection occurs inside the tube and heat escapes greatly. In addition, because the water conduit tube is not held sufficiently in the cylindrical glass tube 2, the glass tube may be damaged due to shaking during transportation, and the use of aluminum fins increases costs. . Furthermore, there is a risk of damaging the vacuum glass tube due to over-tightening of the screws during assembly.

(4) Purpose of the Invention The present invention solves the above-mentioned conventional problems, and aims to prevent convection by eliminating contact between the air inside the vacuum glass tube and the outside air, and also to prevent damage to the glass tube due to shaking of the water pipe. With the goal.

(5) Structure of the Invention (6) Embodiment of the Invention This is a sectional view of a vacuum glass tube and its fixture.
14 is a selective absorption membrane; 15 is a heat-resistant convection prevention plate made of, for example, silicone rubber, disposed inside the inner glass tube 13; 16 is a vacuum glass tube that holds the water conduit 5; 13 is a high-temperature insulating material for closing the opening; 17 is a heat insulating material disposed around the header pipes 6a and 6b;
8 and 19 indicate parts constituting a container that houses and protects the high-temperature insulating material I6, the heat insulating material 17, and the header pipes 6a and 6b; hereinafter, 18 will be referred to as a front cover and 19 will be referred to as a front base. Reference numerals 20 and 21 denote a front holder and a rear holder for the vacuum glass tube 11, respectively, and 22 a protective cover for the closed tube section 27 of the vacuum glass tube 11, both of which are rubber molded products. Reference numerals 23 and 24 are fixing devices for the rear holder 21, and hereinafter, 23 will be referred to as a rear cover and 24 will be referred to as a rear heath. 25 and 26 are screws fixed to the front base 19 and the rear hese 24.

FIG. 3 is a perspective view of the convection prevention plate 15, which is a disc-shaped silicone rubber plate with four portions 15a formed without the water conduit 5 passing therethrough. The high-temperature insulating material 16 is formed into a rectangular parallelepiped, as shown in FIG. 4, with circular notches 31 at both ends.
A plurality of (six in the figure) are provided, and one block of one high-temperature insulating material 16 is used for a plurality of vacuum glass tubes. Further, the water conduit 5 communicates with the circular openings at both ends of the notch 31 as shown in the figure.The shape of the notch is not limited to that shown, and other shapes are also possible.

FIG. 5 is a perspective view of the front holder 20 for a vacuum glass tube, with through holes 3 in the holder block 36, which is a rectangular parallelepiped rubber molded product.
2 is provided, and a plurality of vacuum glass tubes are held with one holder block. Therefore, the diameter of the through-hole 32 is made large enough to allow insertion of a vacuum glass tube, and the number of through-holes per block is the same as the number of cuts in the high-temperature insulating material 16, but the number is selected as appropriate. The rear holder 21 is also formed in the same manner.

FIG. 6 is a perspective view of a holder block showing a method of connecting the front and rear holders 20, 21. As shown in the figure, each block 33 has a convex portion 33a on one of the connecting sides, and the convex portion on the other side. Four parts 33b are formed that match the part 33a, and the convex part 33a of each block 33 and the concave part 33b of the adjacent block are formed.
Connect in combination with.

FIG. 8 is a partially cutaway exploded perspective view for explaining the assembly of the solar collector with the above-mentioned configuration.To explain this with reference to FIG. After passing the water pipe 5 through the high temperature insulation material 16 and then placing the front base 19, the insulation material 17 is installed around the nodder pipes 16a and 16b.

The rear front holder 20 is placed in front of the high temperature heat insulating material 16 through the water conduit 5, and then the front cover 18 is covered to form a container. In this case, the front cover 18,
A container is formed by integrating the front holder 20 and the front base 19, and at this time, a screw 3 having the shape shown in FIG.
5 or by arranging, for example, a metal insert pipe 37 inside the holder block 33 as shown in FIG. 6, over-tightening of the screws can be prevented. For this purpose, the length of the metal insert pipe 37 in the vertical direction or the length of the unthreaded portion of the screw 35 is smaller than the height of the block 33 (the length in the vertical direction as seen in the figure). , is set to be larger than the diameter of the vacuum glass tube 11.

Next, after attaching a convection prevention plate 15 made of silicone rubber to the water conduit 5, the water conduit 5 is inserted into the inner glass tube 13 of the vacuum glass tube 11, so that the opening of the glass tube is aligned with the front holder 20.
It is arranged so that it passes through the 0 through hole and reaches the high temperature insulation material 16.

Next, after passing the glass tube head through the through hole of the rear holder 21, the protective cover 22 is attached, and these are attached to the rear cover 23.
, and is fixed to the rear base 24 with screws 26. In this case, either a metal insert pipe 37 is provided in the rear holder 21 in the same way as the front holder 20, or a screw 3 shown in FIG.
5 prevents damage to the vacuum glass tube due to over-tightening of the screws.

Then perform the above steps for other blocks,
The blocks are then connected to form a solar collector. Note that the number of blocks is determined as necessary.

The solar collector according to the present invention configured as described above includes a silicone rubber convection prevention plate 15 disposed on a vacuum glass tube.
The interior of the inner glass tube 13 is divided into a plurality of parts, and the opening is closed by a high-temperature insulating shell 16, which prevents the air inside the tube from interfering with the outside air, and also prevents the water conduit 5 from leaking. Since it is held by the convection prevention plate 15, damage to the force glass tube due to shaking inside the tube is also prevented. Furthermore, since G-shaped aluminum fins are not used as in the conventional case, costs can be reduced.

On the other hand, by fixing multiple vacuum glass tubes with one holder and making them into a block, assembly becomes easier and there is no direct contact of metal with the vacuum glass tubes, which reduces the loss of heat due to conduction. There is a certain effect.

(7) Effects of the Invention As explained in detail, according to the present invention, air convection within the vacuum force tube is prevented, damage caused by shaking during transportation, etc. does not occur, and cost reduction and assembly are possible. Since it provides a solar collector that can be simplified, it is highly effective in improving the energy conversion efficiency of the solar collector and reducing the cost of the solar i%5 utilization system. This also solves the problem of damage to the vacuum tube wall due to over-tightening of the screws.

[Brief explanation of drawings]

Figure 1 is a partially cutaway exploded perspective view of a conventional vacuum glass tube, Figure 2 is a sectional view of the vacuum glass tube and its fixture that constitute the solar collector according to the present invention, and Figure 3 is a convection prevention device. Fig. 4 is a perspective view of the plate, Fig. 4 is a perspective view of the high-temperature insulating material, Fig. 5 is a perspective view of the vacuum glass tube holder, Fig. 6 is a perspective view showing the connection of the holder, and Fig. 7 is a perspective view of the holder fixed. FIG. 8 is a partially cutaway exploded perspective view of the solar collector according to the present invention. 1.11-m-vacuum glass tube, 2,13--inner glass tube, 3,12--outer glass tube, 4--aluminum fin, 5-water conduit tube, 6a, 6b--heso goo tube , 14-
Selective absorption membrane, 15--convection prevention plate, 16-high temperature insulation material, 17-thermal insulation material, 18-front cover, 19--front base, 20-front holder, 21-rear holder , 22・-
・Protective cover, 23-Rear cover, 24...-Rear base, 25.26.35-Screw, 32-...Through hole, 36
−・−Holder Pro Tsuku 37−・−Metal insert pipe patent Applicant Nebon Co., Ltd. Agent Patent attorney Akira Kukimoto

Claims (3)

[Claims] (1) A solar collector using a vacuum glass tube consisting of an inner glass tube and an outer glass tube with a water conduit for heat medium circulation inside, and a convection prevention plate arranged inside the inner glass tube. A solar heat collector characterized in that a plurality of such vacuum glass tubes are fixed as a unit with a holder, and the open ends of the vacuum glass tubes and the periphery thereof are closed with a heat insulating material. (2) The solar collector according to claim 1, wherein the holder for the vacuum glass tube is made of an elastic material. (3) The solar collector according to claim 2, characterized in that a strong member is provided inside the vacuum glass tube holder.