KR101180728B1 - Solar Collector Module - Google Patents

Abstract

PURPOSE: A solar collector is provided to prevent a vacuum glass tube from becoming damaged due to the thermal expansion of a heat medium pipe. CONSTITUTION: A solar collector comprises a reflection plate and a plurality of heat collection units(100). The heat collection units collect the thermal energy of sunlight reflected from the reflection plate. The heat collection units comprise a vacuum glass tube(110), a heat collection plate(120), and a plurality of heat medium pipes(130). The heat collection plate is placed inside the vacuum glass tube. The heat medium pipes are closely attached to the heat collection plate, and transfer the heat from the heat collection plate to heat mediums. The heat medium pipes comprise an inflow pipe(131), a discharge pipe(132), and a bent pipe(133). The bent pipe is formed while the inflow pipe and the discharge pipe are bent.

Description

Solar Collector {Solar Collector Module}

The present invention relates to a solar collector, and to a solar collector capable of raising the temperature of the heat medium filled therein by collecting solar heat.

The present invention relates to a solar collector, more specifically

Solar energy is an unlimited energy source, and it can be said that the collector which collects this energy as the energy which is easy to use is a basic structure for using the solar energy efficiently.

As a method for increasing the efficiency of the collector, a device using a vacuum technology to prevent the incident energy from being discharged to the outside and a heat transfer tube which is a high efficiency heat transfer element has been proposed to facilitate the transfer.

Figure 1 shows the vacuum tube solar collector.

The vacuum tube solar collector 50 shown in FIG. 1 includes a heat collecting plate 10 for collecting solar energy; A heat medium tube 30 which is joined to the heat collecting plate 10 so as to be heat transfer so that heat of the collected solar energy can be absorbed into the working fluid therein; A glass tube 40 surrounding the heat collecting plate 10 and the heat medium tube 30 to form a vacuum therein; It is configured to include, the heat collecting plate 10 is the center of the arc is joined to the heat medium tube 30 and the shape of the cross section based on the longitudinal direction bent from the left and right, respectively around the heat medium tube 30 The heat medium tube 30 is positioned at the center of the glass tube 40 so that the curved surfaces of the left and right sides of the heat collecting plate 10 do not interfere with the irradiated solar energy. (20) is characterized by having the same degree of curvature at the left and right centers on the heat medium tube (30).

However, the vacuum tube solar collector 50 is joined to the heat medium tube 30 in the form of a tube passing through the center of the heat collecting plate 10 and receives heat energy from the heat collecting plate 10 to be heat exchanged.

By the way, the heat medium tube 30 is located in the center of the heat collecting plate 10, the heat energy at both ends of the heat collecting plate 10 is transferred to the center of the heat collecting plate 10, there is a problem that the heat energy is lost.

In addition, as the heat medium tube 30 is thermally expanded, a portion in which the heat medium tube 30 is joined to the glass tube 40 is damaged.

The background technology of the present invention is disclosed in Republic of Korea Patent Publication No. 0692949.

Republic of Korea Patent Publication No. 10-0692949 (2007.03.05)

The present invention has been made to solve the problems described above, an object of the present invention is to efficiently transfer the heat energy transferred to the heat collecting plate of the solar collector to the heat medium tube, and that the vacuum glass tube is broken by the thermal expansion of the heat medium tube It is to provide a solar collector that can be prevented.

The present invention provides a solar heat collector (1000) comprising a reflector (200) for reflecting sunlight from the sun and a plurality of collectors (100) for collecting heat energy of sunlight reflected from the reflector (200). The heat collecting part 100 of the solar collector 1000 has a vacuum glass tube 110 which is manufactured in a sealed tube shape at both ends and has a vacuum inside thereof, and a heat collecting plate which is manufactured in a plate shape and provided inside the vacuum glass tube 110 ( 120, and a plurality of heat medium pipes 130 formed in a tubular shape and passing through the heat exchange medium, are in close contact with the heat collecting plate 120 to receive heat from the heat collecting plate 120, and transfer the heat to the heat exchange medium. The heat medium tube 130 is characterized in that it has a single inlet pipe 131 and the discharge pipe 132.

In addition, when a plurality of the heat collecting part 100 is connected in the longitudinal direction, the inlet pipe 131 and the discharge pipe 132 is characterized in that the connection.

In addition, the heat collecting plate 120 is produced in a long plate shape, characterized in that the cross section in the width direction is produced in a convex shape in the lower direction.

In addition, the heat collecting plate 120 is made long in the shape of a plate, the widthwise cross-section is convex in the upper direction is formed continuously, characterized in that the heat medium tube 130 is located on the top of the convex shape.

In addition, the reflective plate 200 is made of a long plate shape, characterized in that the cross-section in the width direction is produced in a convex shape in the lower direction.

In addition, the reflective plate 200 is made of a long plate-like, characterized in that the widthwise cross-section convex in the lower direction is formed continuously.

In addition, the heat medium tube 130 is characterized in that bonded to the heat collecting plate 120 by ceramic welding.

In addition, the heat collecting plate 120 is characterized in that the coating with titanium.

In addition, the heat collecting part 100 is characterized in that the cross section of the vacuum glass tube 110 is formed in an elliptic shape.

The solar collector of the present invention may be provided with a plurality of heat medium tubes on the heat collecting plate to efficiently transfer heat energy transferred to the heat collecting plate of the solar heat collector to the heat medium tubes, thereby increasing heat transfer efficiency.

In addition, the heat collecting portion includes a bent tube, which can prevent the vacuum glass tube from being damaged by thermal expansion of the heat medium tube.

1 is a plan view of a heat collecting part of a conventional solar collector
2 is a perspective view of a solar collector of the present invention
3 is a perspective view of the heat collecting part of the present invention
4 is a plan view of the heat collecting part of the present invention
Figure 5 is a cross-sectional view of a first embodiment of the solar collector of the present invention
Figure 6 is a cross-sectional view of a second embodiment of the solar collector of the present invention
7 is a cross-sectional view of a third embodiment of the solar collector of the present invention

Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

However, the accompanying drawings are only examples to illustrate the technical idea of the present invention in more detail, and thus the technical idea of the present invention is not limited to the accompanying drawings.

With reference to FIG. 2, the general form and structure of the solar collector 1000 of this invention are demonstrated.

The solar collector 1000 of the present invention includes a reflector 200 reflecting sunlight from the sun and a plurality of collectors 100 that collect heat energy of sunlight reflected from the reflector 200.

In addition, when a plurality of the heat collecting parts 100 are connected, the heat medium pipe 130 of the heat collecting part 100 is connected to be long in the longitudinal direction.

At this time, the reflector 200 is preferably made long in the shape of a plate, the cross section in the width direction is preferably produced in a convex shape in the lower direction is preferably produced so that the heat energy from the sun can be concentrated in the heat collecting portion (100).

With reference to FIG. 3 and FIG. 4, the general form and structure of the heat collecting part 100 of this invention are demonstrated.

The heat collecting part 100 includes a vacuum glass tube 110, a heat collecting plate 120, and a heat medium tube 130.

The vacuum glass tube 110 is manufactured in the form of a closed tube at both ends, the inside is made of a vacuum in order to prevent the heat energy from the reflecting plate 200 and heat energy directly from the sun is transferred to the outside by convection. do.

The heat collecting plate 120 is manufactured in a plate shape and is located inside the vacuum glass tube 110.

The heat medium tube 130 is formed in a tubular shape and a heat exchange medium passes therein, is in close contact with the heat collecting plate 120, receives heat from the heat collecting plate 120, and transmits the heat to the heat exchange medium.

At this time, the heat medium tube 130 has a single inlet tube 131 and the discharge tube 132, a portion of which is exposed to both ends of the vacuum glass tube 110, the portion in close contact with the heat collecting plate 120 is a plurality. It is characterized in that divided into three heat medium tube (130).

That is, the heat medium tube 130 is a plurality of heat medium tube 130 is in close contact with the heat collecting plate 120, when the heat collecting plate 120 is separated into a single heat medium tube is collected in the inlet pipe 131 and The discharge pipe 132 is formed.

In this case, the inlet pipe 131 and the discharge pipe 132 may further include a bent pipe 133, a part of which is formed to be bent.

The bent tube 133 is formed in the inlet tube 131 and the discharge tube 132 in a portion located inside the vacuum glass tube 110, the heat medium tube 130 is expanded by heat in the longitudinal direction When extended, the bending interval of the bending tube 133 is narrowed.

Therefore, the heat collecting part 100 may prevent the inlet pipe 131 and the discharge pipe 132 from being bonded to the vacuum glass tube 110 from being damaged by thermal expansion of the heat medium tube 130. Can be.

When the plurality of heat collecting parts 100 are connected, the inlet pipe 131 and the discharge pipe 132 are connected to the heat collecting part 100 in the longitudinal direction, the heat medium is used for the high temperature 150 ℃ ~ 300 ℃ It can be used as a solar collector (1000).

In addition, since the plurality of heat medium tubes 130 are in close contact with the heat collecting plate 120, heat energy may be efficiently transferred from the heat collecting plate 120 to the heat medium tubes 130.

In addition, the heat medium tube 130 is bonded to the heat collecting plate 120 by ceramic welding.

At this time, the heat medium tube 130 is in close contact with one surface of the heat collecting plate 120, and then the ceramic body is welded to a portion corresponding to the portion in which the heat medium tube 130 is in close contact with the heat collecting plate (120). 120).

In addition, the heat collecting plate 120 is preferably coated with titanium.

When the heat collecting plate 120 is coated with titanium, the thermal conductivity is improved, thereby increasing the thermal efficiency of the solar heat collector 1000.

In addition, the vacuum glass tube 110 may be manufactured to have an elliptical cross section in the longitudinal direction.

In this case, when the vacuum glass tube 110 is manufactured in an elliptical shape, the internal volume may be reduced to increase the thermal efficiency, and a larger width direction length of the heat collecting plate may be used, thereby increasing the thermal efficiency of the solar collector 1000. .

5 to 7, various embodiments of the solar collector 1000 of the present invention will be described.

The heat collecting plate 120 may be manufactured to have a long plate shape, and may be manufactured to have a cross-section convex in a downward direction in a width direction (see FIG. 5).

When the heat collecting plate 120 is manufactured in a convex shape in the downward direction, the surface area of the heat collecting plate 120 can be widened in the limited internal space of the vacuum glass tube 110, so that the heat collecting plate 120 absorbs more heat energy. There is an advantage to this.

In addition, the heat collecting plate 120 is made long in a plate shape, the cross section in the width direction is formed in the M-shape convex shape in the upper direction continuously, the heat medium tube 130 may be located at the top of the convex shape. (See Figure 6)

At this time, since the heat medium tube 130 is located at the top of the convex shape, it is easy to access from the side to easily weld to the heat collecting plate 120, the surface area of the heat collecting plate 120 is also widened, the solar heat collector 1000 Can increase the thermal efficiency.

In addition, the reflecting plate 200 may be manufactured to have a long plate shape, and may be formed in a W shape so that the cross section of the width direction is convex downward.

At this time, when the shape of the reflector 200 receives sunlight, the sunlight is made to be concentrated in the heat collecting portion 100, the direct sunlight directly transmitted from the sunlight as well as other objects or reflectors of sunlight Even scattering radiation that is reflected and delivered to the light emitting unit has an advantage of transferring heat energy to the heat collecting unit 100.

Therefore, the solar collector 1000 of the present invention includes a plurality of the heat medium tubes 130 on the heat collecting plate 120 to efficiently transfer the heat energy transferred to the heat collecting plate 120 of the solar heat collector 1000. Transfer to 130 may increase the heat transfer efficiency.

In addition, the heat collecting part 100 is formed with a bent tube 133 in the inlet pipe 131 and the discharge pipe 132, so that the heat transfer pipe 130 is damaged by the thermal expansion of the vacuum glass tube 110 Can be prevented.

1000: solar collector
100: heat collecting part
110: vacuum glass tube
120: heat collecting plate
130: heat medium tube
131: inlet pipe
132 discharge tube
133: bend pipe
200: reflector

Claims (10)

In the solar collector 1000 including a reflector 200 reflecting sunlight from the sun and a plurality of collectors 100 for collecting the heat energy of the sunlight reflected from the reflector 200,
The heat collecting part 100 of the solar collector 1000
A vacuum glass tube 110 having both ends sealed in a tube shape and having a vacuum inside thereof;
A heat collecting plate 120 formed in a plate shape and provided inside the vacuum glass tube 110; And
It is formed in a tubular shape, the heat exchange medium passes therein, and is in close contact with the heat collecting plate 120 includes a plurality of heat medium pipe 130 to receive heat from the heat collecting plate 120 to transfer to the heat exchange medium,
The heat medium tube 130 has a single inlet tube 131 and discharge tube 132, the inlet tube 131 and the discharge tube 132 includes a bent tube 133 is formed to be bent Featuring a solid color.
delete The method of claim 1,
Solar collectors, characterized in that the inlet pipe 131 and the discharge pipe 132 is connected when a plurality of the heat collecting portion 100 is connected in the longitudinal direction.
The method of claim 1,
The heat collecting plate 120 is made long in the shape of a plate, the solar heat collector, characterized in that the widthwise cross-section is produced in a convex shape in the lower direction
The method of claim 1,
The heat collecting plate 120 is formed in a long plate shape, the widthwise cross-section is convex in the upper direction is continuously formed, the heat collector tube 130 is characterized in that located in the top of the convex shape.
The method of claim 1,
The reflector 200 is made of a long plate shape, the solar collector, characterized in that the cross-section in the width direction is produced in a convex shape in the lower direction.
The method of claim 1,
The reflector 200 is made of a long plate shape, the solar collector, characterized in that the widthwise cross-section is formed convex in the lower direction continuously.
The method of claim 1, wherein
The heat medium tube 130 is a solar collector, characterized in that bonded to the heat collecting plate 120 by ceramic welding.
The method of claim 1,
The heat collecting plate 120 is a solar collector, characterized in that the coating with titanium.
The method of claim 1,
The collector 100 is a solar collector, characterized in that the cross section of the vacuum glass tube 110 is formed in an ellipse shape.

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