KR20130010532A - Evacuated solar collector module with two tube module each side of one header - Google Patents

Abstract

PURPOSE: A solar heat collector with a heat pipe type vacuum pipe formed on both sides of a head unit is provided to improve thermal efficiency and to prevent a heat collecting plate from overheating in the summer. CONSTITUTION: A solar heat collector(50) with a heat pipe type vacuum pipe formed on both sides of a head unit comprises a heat collection plate(10), a heat pipe(20), a vacuum pipe(30), and a header unit(40). The vacuum pipe wraps the heat collection plate and heat pipe. The header unit includes a condensing unit inside to deliver the heat of the heat pipe to the outside. The vacuum pipe is horizontally installed for easy installation of the heat collector. The heat collection plate is inclined at a predetermined angle depending on the installation place of the heat collector.

Description

Evacuated solar collector module with two tube module each side of one header}

The present invention relates to a solar heat collector in which a heat pipe type single vacuum tube is formed on both sides of a header portion, and more specifically, even if the installation angle of the single vacuum tube collector is installed at any angle, the inclination angle of the heat collecting plate can be formed at a desired angle. It is possible to collect in the best condition, the efficiency of the collection is high, and the collector can be installed in consideration of the design aspect of the building.Even if the collector is installed at a low angle, the collector plate is installed at a high angle to prevent overheating in the summer. By installing the vacuum tubes on both sides of one header part, the manufacturing cost of the collector header part is reduced, thereby reducing the overall price of the collector, reducing the installation area and the heat loss area, and improving the thermal performance. Heat pipe type that reduces construction cost by reducing subsidiary materials such as pipe insulation A vacuum tube relates to the solar collector which is formed on both sides of a header part.

In general, solar collectors that collect solar heat are largely divided into flat and vacuum tubes (single and double vacuum tubes). In this case, the installation angles of all conventional collectors are winter heating systems. When the sun comes in at noon, the direct sunlight is about 60 degrees, which is the angle of vertical incidence, so that it can increase the number of winter collections.The system that needs to be concentrated in the summer season is suitable for summer collection, that is, the direct sunlight at noon It should be installed around 10 degrees, the angle of incidence.

Here, the flat solar collector is formed of a rectangular flat plate body, while forming a heat collecting plate with a special coating on the surface to absorb the sun's rays on a thin metal plate made of copper or aluminum, etc., On one surface of the heat collecting plate, a plurality of thin paper tubes made of copper and the like are welded at a predetermined interval to be inserted into a rectangular frame and a transparent cover is formed on the upper portion thereof to form an integral collector.

In the conventional flat solar collector, solar rays primarily heat the heat collecting plate, and the heated heat collecting plate transmits thermal energy to the heat medium inside the branch pipe formed on one side, and the heat exchanged heat medium is joined in the main pipe of the heat collector to store heat storage tank or heat exchange. It is formed to provide heat energy collected in the group.

On the other hand, the solar heat collector, which is a conventional heat pipe type vacuum tube formed on both sides of the header portion has a glass tube shape and is formed to block heat loss due to convection by vacuuming a closed space in contact with the solar heat collecting surface.

At this time, the heat collector is formed on both sides of the heat pipe type vacuum tube, as shown in Figure 1 and 2, a method of using one glass tube (2) and double vacuum tube type using two glass tubes. It is divided in the way.

First, a method of using one glass tube 2 inserts a heat collecting plate 4 equipped with a heat pipe 3 inside the glass tube 2, and heat pipe 3 to the top of the glass tube 2. ) Is sealed with a metal stopper in a protruding state, and the inside thereof is vacuumed to prevent solar heat collected from the surface of the heat collecting plate from being lost to the outside by convection.

The heat collector 1, in which the heat pipe type vacuum tube of this type is formed on both sides of the header part, has a complicated process due to the problem of bonding glass and metal in sealing the upper end of the glass tube 2 with a metal stopper. There is a need arises, resulting in problems of durability and economics.

In addition, the method of using the two glass tubes (2) in the form of a double vacuum tube forms a double tube by vacuum-processing the space between the outer tube and the special surface-treated heat collecting tube for solar heat collection, and to the inside of the heat collecting tube It fills the water and seals the upper part of the double tube with an insulating cap to heat the water filled inside the heat collecting tube.

Here, the space between the outer tube and the collecting tube to block the heat loss to the outside due to the convection of air due to the vacuum treatment.

However, in the case of the single vacuum tube collector 1 to which the heat pipe 3 is applied, as shown in FIG. 1, the header part 5 of the collector 1 having the condenser should be installed at the upper end. Therefore, in order to minimize summer heat collection and increase winter heat collection, such as for heating, the installation angle of the heat collector 1 should be 60 degrees or more. In this case, when installed on the roof can not only be an appearance problem, but also difficult to install.

In addition, even if the installation angle of the collector 1 is set to 60 degrees or more, the summer season receives a lot of high-temperature solar heat, thereby overheating the tube 2 and the heat pipe 3, thereby causing a problem of breakage. do.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems,

Even if the installation angle of the single vacuum tube collector is installed at any angle, the angle of inclination of the collector plate can be formed at the desired angle, so that it can be collected under the best conditions, the heat collection efficiency is high, and the collector is considered in consideration of the design aspect of the building. Even if the collector is installed at a low angle, an object of the present invention is to provide a solar collector, in which heat pipe type vacuum tubes are installed on both sides of the header to prevent overheating in the summer by installing the collector plate at a high angle.

In addition, by installing the vacuum tubes on both sides of one header portion, the manufacturing cost of the collector header portion is reduced, thereby lowering the overall price of the collector, reducing the installation area and the heat loss area, and improving the thermal performance. And it is an object of the present invention to provide a solar heat collector that is formed on both sides of the heat pipe type vacuum tube in which the construction cost is reduced by reducing the auxiliary materials such as pipe insulation.

In order to achieve the above object, the present invention is a heat collecting plate formed to collect solar energy, and a heat pipe that is integrally attached to the heat collecting plate and the heat of the solar energy collected from the heat collecting plate is absorbed into the working fluid therein, and transfers heat; A heat pipe type including a vacuum tube surrounding the heat collecting plate and the heat pipe to form a vacuum therein, and a header unit configured to receive the heat of the heat pipe and to receive the heat from the heat pipe while fixing the vacuum tube. In the solar collector, in which vacuum tubes are formed on both sides of the header portion,

The vacuum tube is installed horizontally to facilitate the installation of the collector at the installation position of the collector, the vacuum tube is formed on one side of the header portion, the collector plate is a predetermined inclination angle around the installation position surface according to the installation position of the collector ( Heat pipe type vacuum tube, characterized in that formed inclined at θ) relates to a solar heat collector formed on both sides of the header portion.

In addition, the heat pipe of the present invention is a heat pipe type vacuum tube, characterized in that the heat pipe is formed in an inclined shape that is lower than the condensation unit so that the evaporated working fluid is transferred to one side from the horizontally installed vacuum tube and the heat collecting plate It relates to a solar collector formed on both sides.

As described above, the solar heat collector in which the heat pipe type vacuum tube of the present invention is formed on both sides of the header part may be formed at the desired angle even if the installation angle of the single vacuum tube collector is installed at any angle. It is possible to collect heat under conditions, and the heat collecting efficiency is increased accordingly, and the collector can be installed in consideration of the design aspect of the building.Even if the collector is installed at a low angle, the collector plate is set at a high angle to prevent overheating in the summer. There is.

In addition, by installing the vacuum tubes on both sides of one header portion, the manufacturing cost of the collector header portion is reduced, thereby lowering the overall price of the collector, reducing the installation area and the heat loss area, and improving the thermal performance. And subsidiary materials such as pipe insulation is reduced, the construction cost is reduced.

1 is a perspective view showing a conventional solar collector,
2 is a schematic view showing a conventional vacuum tube,
3 is a perspective view showing a solar heat collector in which a heat pipe type vacuum tube according to an embodiment of the present invention is formed on both sides of a header part,
4 is a cross-sectional view showing a solar heat collector in which a heat pipe type vacuum tube according to an embodiment of the present invention is formed on both sides of a header part,
5 is a schematic view showing the installation of a collector according to an embodiment of the present invention,
Figure 6 is a side cross-sectional view showing a vacuum tube according to an embodiment of the present invention,
Figure 7 is a graph showing the change in the amount of solar plate monthly absorption plate according to the installation angle of the heat collecting plate according to an embodiment of the present invention.

The present invention has the following features to achieve the above object.

The present invention provides a heat collecting plate which is formed to collect solar energy, a heat pipe that is integrally attached to the heat collecting plate and the heat of solar energy collected from the heat collecting plate is absorbed by the working fluid therein to transfer heat, and a vacuum is formed therein. The heat pipe type vacuum tube including a vacuum tube surrounding the heat collecting plate and the heat pipe, and a header portion provided with a condensation portion inside the heat pipe while receiving the heat of the heat pipe while transmitting the heat pipe to both sides of the header portion, while fixing the vacuum tube. In solid color formed,

The vacuum tube is installed at a horizontal position (an angle close to horizontal when the horizontal operation is not possible) to facilitate the installation of the collector at the installation position of the collector, and the vacuum tube is formed on both sides of one header part, and the collector plate is installed at the collector position. It characterized in that the inclined at a predetermined inclination angle (θ) around the installation position surface.

The present invention having such characteristics can be more clearly described by the preferred embodiments thereof.

Before describing the various embodiments of the present invention in detail with reference to the accompanying drawings, it can be seen that the application is not limited to the details of the configuration and arrangement of the components described in the following detailed description or shown in the drawings. will be. The invention may be embodied and carried out in other embodiments and carried out in various ways. It should also be noted that the device or element orientation (e.g., "front," "back," "up," "down," "top," "bottom, Expressions and predicates used herein for terms such as "left," " right, "" lateral, " and the like are used merely to simplify the description of the present invention, Or that the element has to have a particular orientation. Also, terms such as " first "and" second "are used herein for the purpose of the description and the appended claims, and are not intended to indicate or imply their relative importance or purpose.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

3 is a perspective view illustrating a solar collector in which a heat pipe type vacuum tube according to an embodiment of the present invention is formed on both sides of a header portion, and FIG. 4 is formed on both sides of a heat pipe type vacuum tube according to an embodiment of the present invention. Figure 5 is a cross-sectional view showing a solar collector, Figure 5 is a schematic diagram showing the installation of a collector according to an embodiment of the present invention, Figure 6 is a side cross-sectional view showing a vacuum tube according to an embodiment of the present invention, Figure 7 is the present invention Figure is a graph showing the change in the amount of insolation monthly absorbing plate according to the installation angle of the collector.

3 to 7, the solar heat collector 50 in which the heat pipe type vacuum tube of the present invention is formed on both sides of the header portion includes a heat collecting plate 10, a heat pipe 20, a vacuum tube 30, It consists of a header part 40.

As shown in FIGS. 3 and 4, the heat collecting plate 10 collects solar energy, collects heat for receiving and heating heat for operating and evaporating a working fluid in the heat pipe 20, and the heat collecting plate 10. ) Is attached to the outer circumferential surface of the heat pipe 20 by ultrasonic welding, etc. The cross-sectional shape of the heat collecting plate 10 is formed in various forms such as a flat plate or a curved shape to increase the heat collecting area.

Here, the heat collecting plate 10 is installed in the interior of the vacuum tube 30, the vacuum tube 30 is installed in the collector 50 according to the installation position of the heat collector 50, that is, the inclined roof or vertical wall, etc. It is installed horizontally to facilitate, and the vacuum tube 30 can be installed vertically in addition to horizontal. The heat collecting plate 10 of the vacuum tube 30 installed according to the installation position of the collector 50 is installed at a desired angle with respect to the installation position surface as shown in FIG. 6. For example, in order to maximize the winter heat collection and to reduce the amount of summer heat that does not need much solar heat, it is formed to be inclined at an inclination angle (θ) of 60 to 90 degrees.

The reason is that the vacuum tube 30 is installed in accordance with one end of the installation position, so that the heat collecting plate 10 installed in such a vacuum tube 30 is also parallel to one end of the installation position, thereby optimizing the inclination angle of the heat collecting plate. Can not install at an angle of can not absorb the amount of heat collected according to the heat load. That is, for example, when the collector 50 is installed on the vertical wall surface, the collector is installed vertically, and the inclination angle of the collector plate 10 is also vertical. Then, the solar heat collection is less than 50-60 degrees, which can be a lot of heat collection in winter, the present invention in the collector 50 installed in such a state to increase the heat absorption of solar heat in the desired season (10) ) Is formed at the angle of the heat collecting plate separately from the angle of the collector 50 in the vacuum tube 30 or to be inclined at an optimum angle that can absorb the heat of the solar most.

Here, only the vertical wall surface described above may be installed by inclining the heat collecting plate 10 at an optimal angle even when installed on a severely inclined or gentle inclined wall surface. The heat collecting plate 10 can be installed directly in the field by integrally manufacturing at an optimal angle in the vacuum tube 30 according to the installation position of the heat collector 50 in the factory.

As shown in FIG. 4, the heat pipe 20 is provided with a working fluid therein and evaporated when heat is transferred, and the evaporated working fluid is transferred in the longitudinal direction of the heat pipe 20, and then heats at one side. The heat pipe 20 is a general heat pipe composed of a condensation part 22 in which the working fluid evaporated through the evaporator 21 and the condensation part 22 in which the working fluid is evaporated. 20 is the structure. At this time, the condensation part of the heat pipe 20 is provided inside the header part 40.

Here, the heat pipe 20 allows the heat of solar energy collected through the heat collecting plate 10 to be absorbed into the working fluid therein, and is heat-bonded with the heat collecting plate 10 for this purpose. As an example, the heat pipe 20 and the heat collecting plate 10 may be joined by ultrasonic welding. In this case, the heat transfer efficiency increases as the area of the heat pipe 20 and the heat collecting plate 10 bonded to each other increases. In addition, the bonding area of the heat collecting plate 10 is widened to increase the transmission efficiency, and the heat pipe 20 and the heat collecting plate 10 may be more firmly coupled.

In addition, the heat pipe 20 is integrally formed on the heat collecting plate 10. At this time, the vacuum tube 30 and the heat collecting plate 10 are horizontally installed, and thus the heat pipe 20 is also horizontally installed. Therefore, the working fluid evaporated by the heat of the heat collecting plate 10 is not properly circulated (between the evaporation portion 21 and the condensation portion 22) because there is no head gradient in the heat pipe 20, and solar heat is not collected. This may occur, and thus heat medium characteristics in the heat pipe 20 may change or may be broken.

In order to solve this problem, the heat pipe 20 of the present invention is formed on the heat collecting plate 10 so as to be inclined so that the evaporator 21 is lower than the condenser 22 on the same horizontal line. That is, the heat pipe 20 end of the heat pipe 20 on the header portion 40 side is transferred to the vacuum pipe 30 side so that the evaporated working fluid in the heat pipe 20 is transferred to one side (condensation portion 22). It is installed higher than the end.

At this time, even if the heat pipe 20 is inclined so that the heat collecting plate 10 is installed horizontally, the head gradient does not occur, but in the present invention, the heat collecting plate 10 in the horizontal state has an inclination angle θ of 60 to 90 degrees. By being inclined, the head gradient (height difference between both ends) of the heat pipe 20 can be formed.

In addition, the condensation part of the heat pipe 20 is bent at a predetermined angle in the header part 40 to increase the inclination angle of the heat pipe 20 so as to be inclined further.

3 to 6, the vacuum tube 30 surrounds the outer side of the heat collecting plate 10 and the heat pipe 20, in this case, so that one side of the heat pipe 20 can protrude a predetermined length. do.

Here, the vacuum tube 30 is bonded to the heat pipe 20 through a bonding member (not shown) so that a vacuum can be formed in a space in which the heat collecting plate 10 and the heat pipe 20 are accommodated. 30 is fixed to one end surface of the header portion 40. At this time, a plurality of vacuum tubes 30 are installed at right angles in the longitudinal direction of the header portion 40.

In addition, the vacuum tube 30 is formed at right angles to both side portions of one header portion 40, as shown in the figure to modularize one. That is, the entire shape of the header portion 40 and the vacuum tube 30 is formed in the form of "+", and conventionally, the vacuum tube 30 is formed only on one side in one header portion 40, so as to form a whole "ㅏ" Is modularized.

As the joining member, it is sufficient that a gap can be prevented at the joining portion of the vacuum tube 30 and the heat pipe 20, and a member of a material having a high sealing property such as a high molecular compound or silicon may be selected and used.

As shown in FIG. 3, the header part 40 is provided with a condensation part of the heat pipe 20 while fixing the end of the vacuum tube 30 to receive heat from the heat pipe 20 to be transmitted to the outside. Device.

Here, the header portion 40 is directly connected to a heat using place such as a heat storage tank (not shown) by a pipe, and the heat source heat-exchanged with the heat pipe 20 in the header portion 40 is connected to a heat using place such as a heat storage tank. The water is delivered, and the cold water having a relatively low temperature is transferred to the header portion 40 from the heat using place such as the heat storage tank. As such, the header portion 40 is a commonly used structure and principle, and no separate technical description is given any further.

10: heat collecting plate 20: heat pipe
21: evaporator 22: condenser
30: vacuum tube 40: header portion
50: collector

Claims (5)

A heat pipe 20 integrally attached to the heat collecting plate 10 and configured to collect solar energy, and heat of solar energy collected from the heat collecting plate 10 is absorbed into an internal working fluid to transfer heat. ), A vacuum tube 30 surrounding the heat collecting plate 10 and the heat pipe 20 to form a vacuum therein, and a condensation part of the heat pipe 20 while fixing the vacuum tube 30 to the inside of the heat pipe. In the solar heat collector (50) in which a heat pipe type vacuum tube including a header portion (40) which receives heat of (20) and transmits it to the outside is formed on both sides of the header portion,
The vacuum tube 30 is horizontally installed to facilitate the installation of the collector 50 at the installation position of the collector 50, the vacuum tube 30 is formed on both sides of one header portion 40,
The heat collecting plate (10) is a solar heat collector, characterized in that the heat pipe type vacuum tube is formed on both sides of the header portion, characterized in that formed inclined at a predetermined inclination angle (θ) around the installation position surface according to the installation position of the collector (50).
The method of claim 1,
The heat pipe 20 is formed in an inclined form in which the evaporator 21 is lower than the condenser 22 so that the evaporated working fluid is transferred to one side from the horizontally installed vacuum tube 30 and the heat collecting plate 10. The solar heat collector, characterized in that the heat pipe type vacuum tube is formed on both sides of the header portion.
The method of claim 2,
The condensation part 22 of the heat pipe 20 is bent at a predetermined angle in the header portion 40 to increase the inclination angle of the heat pipe 20, characterized in that the heat pipe type vacuum tube is formed on both sides of the header portion Solid color formed on.
The method of claim 1,
Since the inclination angle θ of the heat collecting plate 10 depends on the installation position of the heat collector 50, the heat collector type vacuum tube is formed on both sides of the header part.
The method of claim 1,
The heat collector having the heat pipe type vacuum tube formed on both sides of the header portion 40 is characterized in that the vacuum tube 30 is horizontally installed so that the header portion 40 is provided at a right angle with the vacuum tube 30 on the side of the vacuum tube 30. .

Images