KR102174111B1 - Solar collector - Google Patents

Abstract

The present invention relates to a solar heat collecting device, including a reflecting plate that reflects sunlight in a hemispherical shape and concentrates sunlight in the center, and a transparent plate that covers the upper portion of the reflector and transmits sunlight at the same time. A light-transmitting reflector coupled to the top and bottom so that the vacuum is vacuumed; A heat collecting part which is penetrated to the center of the lower end of the reflector and absorbs radiant heat of sunlight concentrated by extending to the inner center of the light transmitting reflector with a predetermined length; A housing for embedding and fixing a lower portion of the light transmitting reflector; A supply pipe positioned under the light transmitting reflector and passing through the housing in a transverse direction to allow the heat medium to flow therein; It is provided at the inner center of the supply pipe and includes a heat transfer unit coupled to the lower end of the heat collecting unit to receive solar heat absorbed by the heat collecting unit to heat the heat medium, and the heat collecting unit is vertically penetrated to the center of the reflector A copper rod for transferring solar heat to the heat transfer unit; It is composed of a graphite crucible that covers the outer surface of the copper rod and absorbs sunlight reflected by the reflector and transfers solar heat to the copper rod. In addition to stability according to thermal stress, thermal conductivity and heat storage performance are improved, as well as heat loss. It relates to a solar heat collecting device that increases blocking and heat absorption rate, increases the efficiency of rapid heating as the heat exchange area is secured as much as possible, and can conveniently mount a plurality of units continuously through modularization.

Description

Solar collector

The present invention relates to a solar heat collecting device, and more specifically, stability according to thermal stress, thermal conductivity and heat storage performance improvement, as well as heat loss blocking and heat absorption rate increase, and rapid heating by securing the heat exchange area as much as possible. The furnace efficiency is increased, and it relates to a solar heat collecting device that can be conveniently installed in a row through modularization.

In general, as a method for using sunlight as an energy source, a method of using a solar cell to generate electric energy by condensing sunlight is widely known.

As described above, as a method of using sunlight in addition to the method of converting sunlight into electric energy, there are various types of collectors that can efficiently collect radiant heat from the sun and use it as an indirect or direct heating source.

Among the heat collectors, a solar heat collector has been developed that collects heat by coating black chromium, etc., which absorbs sunlight into the inside of a vacuum tube having a double glass wall, and in particular, reduces heat loss due to convection in a vacuum state to increase heat collection efficiency.

A heat collector such as Patent Document 1 has the advantage of excellent heating effect because the heat medium is directly in contact with the heat collecting surface.However, since the heat medium with different temperatures is mixed with each other in stages, the circulation of the heat medium is very slow or overlapping and convection circulation There is a problem in that the heat exchange efficiency decreases due to this slowness.

In addition, when a vacuum tube made of glass is bonded to a heat transfer unit made of metal, it is not easy to bond firmly due to the difference in physical properties between glass and metal, causing leakage and frequent breakage of the contact surface during bonding.

In addition, the vacuum tube collector must be exposed to the outside to absorb sufficient solar heat, but if the vacuum tube collector is exposed to the outside, it can be easily damaged, and when the vacuum tube is damaged, the heat medium of the heat transfer unit leaks, making maintenance and repair difficult. I need this.

Further, in the case of Patent Document 2, since the structure is assembled for circulation of the heat medium, there is a problem in that the efficiency of solar heat collection is inferior and it is inconvenient to assemble multiple connections.

KR 10-0999513 B1 KR 10-2011-0094477 A

In order to solve the above-described problem, the present invention is a light-transmitting reflector that concentrates sunlight in a vacuum state, and a heat collecting unit having a graphite crucible absorbs solar heat and heats the medium through a heat transfer unit connected to the heat collecting unit while being provided inside the medium supply pipe. It is configured so that the stability according to thermal stress, thermal conductivity and heat storage performance, as well as heat loss blocking and heat absorption rate are increased.By securing the heat exchange area as much as possible, the efficiency of rapid heating increases, and through modularization It is an object of the present invention to provide a solar heat collecting device that can be conveniently installed in succession.

In order to achieve the above object, the present invention includes a reflecting plate that reflects sunlight to the inside in a hemispherical shape and concentrates the sunlight in the center, and a floodlight that covers the upper part of the reflector and transmits sunlight at the same time. A light-transmitting reflector coupled to the top and bottom so that the interior is vacuumed; A heat collecting part which is penetrated to the center of the lower end of the reflector and absorbs radiant heat of sunlight concentrated by extending to the inner center of the light transmitting reflector with a predetermined length; A housing for embedding and fixing a lower portion of the light transmitting reflector; A supply pipe positioned under the light transmitting reflector and passing through the housing in a transverse direction to allow the heat medium to flow therein; It provides a solar heat collecting device, characterized in that it comprises a heat transfer unit provided in the inner center of the supply pipe, coupled to the lower end of the heat collecting unit to receive the solar heat absorbed by the heat collecting unit to heat the heat medium.

Here, the heat collecting unit is vertically coupled to the center of the reflecting plate, a copper rod for transmitting solar heat to the heat transfer unit; It is characterized in that it is made of a graphite crucible that covers the outer surface of the copper bar to absorb sunlight reflected by the reflector and transfer solar heat to the copper bar.

In addition, it is characterized in that the solar heat collecting device of the present invention configured as described above is continuously connected to each other by further comprising coupling ports for interconnecting the other supply pipes at both ends of the supply pipe.

By providing the present invention configured as described above, along with stability according to thermal stress, thermal conductivity and heat storage performance are improved, as well as heat loss blocking and heat absorption rate are increased, and efficiency by rapid heating increases as the heat exchange area is maximized. And, through modularization, there is an effect that a plurality of them can be conveniently installed continuously.

1 is a block diagram showing a solar heat collecting device according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the same technical field can easily implement the present invention.

As shown in FIG. 1, the solar heat collecting device of the present invention has a reflective plate 110 that reflects sunlight to the inside in a hemispherical shape and concentrates it at the center, and covers the upper portion of the reflective plate 110. A light-transmitting reflector 100 is provided that includes a light-transmitting plate 120 that transmits sunlight and is coupled to the top and bottom so that the interior is vacuumed.

In addition, it has a heat collecting unit 200 which is coupled through the lower center of the reflector 110 and extends to the inner center of the light transmitting reflector 100 to a predetermined length to absorb radiant heat of concentrated sunlight.

In the case of the reflective plate 110 of the light transmitting reflector 100, sunlight entering a straight line through a parabolic area in a hemispherical shape may be reflected to concentrate sunlight on the heat collecting unit 200 provided in the center.

At this time, by covering the upper side of the reflective plate 110 with the light-transmitting plate 120, a vacuum state can be maintained inside the light-transmitting reflector 100, and a reduction in reflective power due to contamination of foreign substances of the reflective plate 110 can be prevented. I can.

Therefore, it is preferable that the reflective plate 110 and the transparent plate 120 of the transparent reflector 100 are sealed to each other.

A housing 400 for filling and fixing a lower portion of the light transmitting reflector 100 may be formed at a lower end of the light transmitting reflector 100.

The housing 400 fills the reflective plate 110 of the light-transmitting reflector 100 with an insulating material 430 of plastic or airgel to partially embed the light-transmitting reflector 100, the heat collecting part 200, and heat transfer from an external impact. It is possible to protect the unit 300 and the supply pipe 410 and minimize the loss of collected heat to the outside.

In addition, a supply pipe 410 through which a heat medium flows inside the housing 400 may be provided at a lower portion of the housing 400 located under the light transmitting reflector 100.

Here, in the case of the supply pipe 410, the supply pipe may include a heat transfer unit 300 that is coupled to the lower end of the heat collecting unit 200 to receive solar heat absorbed by the heat collecting unit 200 and heat the heat medium. 410) is provided in the inner center.

Therefore, the heat collecting part 200 is coupled to the center of the reflective plate 110 in a fastening manner, so that a part of the lower end is exposed and the heat transfer part 300 having a shape that increases the heat transfer area is exposed to the heat collecting part 200. It is combined with a fastening method to form an integral part.

On the other hand, in the case of the supply pipe 410, when the heat medium is heated by the heat transfer part 300, the length portion of the heat transfer part 300 is as much as the position of the heat transfer part 300 so that the flow rate of the heat medium supplied through the supply pipe 410 can be varied. Can be extended further.

In addition, the heat collecting unit 200 is vertically coupled to the center of the reflective plate 110, the copper rod 210 for transmitting solar heat to the heat transfer unit 300; It consists of a graphite crucible 220 that covers the outer surface of the copper bar 210 to absorb sunlight reflected by the reflector 110 and transfer radiant heat to the copper bar 210.

That is, graphite, which is a material constituting the graphite crucible 220, is a black material that is close to a black body, and has a very high absorption and thermal conductivity due to sunlight compared to other objects, thereby maximizing heat collection efficiency.

On the other hand, it is possible to continuously connect and install the solar heat collecting device of the present invention configured as described above by further comprising coupling holes 420 for interconnecting the other supply pipes 410 at both ends of the supply pipe 410.

That is, the present heat collecting device can be installed in a plurality of pipes in response to the incidence of sunlight by connecting pipes continuously by the coupling hole 420, so that it can be used as a large-capacity solar heat collecting device.

On the other hand, a housing 400 is further provided below the light-transmitting reflector 100 to embed and fix a lower portion of the light-transmitting reflector 100, and the supply pipe 410 penetrates the housing 400 in a horizontal direction. Can be formed.

At this time, at both ends of the supply pipe 410, the solar heat of the present invention is configured as a unit (module) by further comprising a coupling hole 420 for interconnecting the supply pipe 410 so that the same housing 400 can be continuously installed. Heat collecting devices can be connected and installed in series.

In addition, since the copper rod 210 is penetratingly coupled to the center of the reflecting plate 110, the copper rod 210 to prevent heat loss to the reflecting plate 110 through contact between the reflecting plate 110 and the copper rod 210, respectively. It is preferable that the insulating tube 130 surrounding the perimeter of the is further provided.

In addition, when the copper rod 210 is exposed to the internal heat medium of the supply pipe 410, the heat medium is prevented from flowing into the vacuum space inside the transparent reflector 100 along the gap of the copper rod 210. A sealing 140 having heat resistance is further provided at an end of the copper rod 210, and a closing cap 150 covering the sealing 140 is included.

That is, the heat medium of the supply pipe 410 is prevented from flowing into the light transmitting reflector 100 along the copper rod 210 through the combination of the sealing 140 and the closing cap 150.

On the other hand, a connector 500 for connecting the end of the copper rod 210 of the 200 and the heat transfer unit 300 to each other is further required.

In the case of the connector 500, a screwed connection plug 510 is protruded at the upper end to correspond to the fastening groove formed at the lower end of the copper rod 210, and screwed connection for connecting the screwed protrusions to both sides by fastening It is preferable that the socket 520 is formed.

That is, the connector 500 is fastened to the end of the copper rod 210 through the connection plug 510 of the connector 500, and the end of the heat transfer unit 300 is fastened through the connection socket 520 The heat transfer part 300 may be located inside the supply pipe 410.

By providing the present invention configured as described above, along with stability according to thermal stress, thermal conductivity and heat storage performance are improved, as well as heat loss blocking and heat absorption rate are increased, and efficiency by rapid heating increases as the heat exchange area is maximized. And, through modularization, there is an effect that a plurality of them can be conveniently installed continuously.

The terms and words used in the specification and claims described above should not be construed as being limited to a conventional or dictionary meaning, and the present inventors appropriate the concept of terms to describe their own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention on the basis of the principle that it can be defined.

Therefore, the configurations shown in the drawings and embodiments described in the present specification are only one of the most preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, and thus can be replaced at the time of application. It is to be understood that there may be a variety of equivalents and variations that may exist.

100: light transmitting reflector
110: reflector
120: floodlight
130: insulation tube
140: sealing
150: closing cap
200: collector
210: copper rod
220: graphite crucible
300: heat transfer unit
400: housing
410: supply pipe
420: coupling
430: insulation
500: connector
510: connection plug
520: connection socket

Claims (4)

The interior includes a reflective plate 110 that reflects and concentrates sunlight on the inside in a hemispherical shape, and a transparent plate 120 that transmits sunlight while covering the upper portion of the reflective plate 110. A light-transmitting reflector 100 that is coupled to each other so as to be vacuumed;
A heat collecting unit 200 which is coupled through the lower center of the reflector 110 and extends to a predetermined length in the inner center of the transparent reflector 100 to absorb radiant heat of concentrated sunlight;
A supply pipe 410 located below the light transmitting reflector 100 and extending in a horizontal direction so that the heat medium flows therein;
It is provided in the inner center of the supply pipe 410, is coupled to the lower end of the heat collecting unit 200 is configured to include a heat transfer unit 300 to receive the solar heat absorbed by the heat collecting unit 200 to heat the heat medium. ,
The heat collecting part 200,
A copper rod 210 which is vertically penetrated to the center of the reflector 110 to transmit solar heat to the heat transfer unit 300;
It is made of a graphite crucible 220 that covers the outer surface of the copper rod 210 and absorbs sunlight reflected by the reflector 110 and transfers solar heat to the copper rod 210,
Between the copper rod 210 and the heat transfer unit 300,
A connector 500 having a connection plug 510 fastened to the lower end of the copper rod 210 and a connection socket 520 fastened to one end of the heat transfer unit 300 is formed. Solar collector.
delete The method according to claim 1,
In the lower part of the light transmitting reflector 100,
A solar heat collecting device, characterized in that a housing (400) is further provided for embedding and fixing a lower portion of the light transmitting reflector (100), and the supply pipe (410) is formed through the housing (400) in a horizontal direction.
The method of claim 3,
The solar heat collecting device of the present invention configured as a unit (module) by further comprising a coupling hole 420 for interconnecting the supply pipe 410 so that the same housing 400 can be continuously installed at both ends of the supply pipe 410 Solar heat collecting device, characterized in that the connection is installed in series.

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