DE102005010461A1 - Solar collector, has protective screen rotatable around vacuum tube between two positions, where screen shields tube against solar radiation in one position, and screen exposes tube to solar radiation in another position - Google Patents

Abstract

The collector has an absorber pipe (11) contained in a vacuum tube (10). A protective screen (12) is provided, where the protective screen is rotatable around the vacuum tube between a position (P1) and another position, where the protective screen shields the vacuum tube against solar radiation in one of the positions and the screen exposes the vacuum tube to the solar radiation in the other position.

Description

The The invention relates to a solar collector with a contained in a radiation-transmissive vacuum tube Absorber tube.

Known are vacuum tube collectors, used primarily for hot water production in single-family homes become. They consist of a series of parallel vacuum tubes, the each contain an absorber tube. The absorber tube is with his Ends connected to a collector, which has a flow line and a return line contains. The vacuum tube is made of glass. It serves for thermal insulation of the absorber tube by a vacuum to prevent convective heat losses.

In Result of long-lasting solar radiation at the same time lower Heat loss overheated the flowing in the solar collector Fluid. In normal operation, the hot fluid in the circulation of the Solar collector pumped into a tank through which the consumer, e.g. a household that is supplied with hot water. In the absence of or low decrease and sustained solar radiation reaches the Tank its maximum allowable Temperature, which is generally of the order of 100 ° C. As a result of the high temperature, the pump that passes the fluid through the absorber pipes are pumping, switched off. Thus enters the so-called "standstill problem", which also as Stagnation is called. If the collector continues to be irradiated, overheating he, so finally due to the high pressure a safety valve responds, fluid off emerges from the collector circuit and vaporizes the fluid in the collector. The fluid is generally a water-glycol mixture. With the vacuum tube collector open at the top evaporates first the water, which makes the remaining glycol high temperatures of up to 200 ° C is exposed and decomposes. The leftovers can be long term lead to blockages and a life shortening of the collector. In addition, the fluid needs to be circulated by a specialist refilled become.

Of the Invention has for its object to provide a solar collector the protection against solar overheating having.

Of the Solar collector according to the invention is designated by the patent claim 1. He has a protective screen on, which pivots around the vacuum tube is between a first position in which he opposes the vacuum tube Solar radiation shields, and a second position in which he the vacuum tube of the Solar radiation exposes.

in the Case of impending overheating the protective screen is turned in front of the vacuum tube, so that he Shades collector against the sun. This will cause overheating the heat transfer fluid prevented; vaporized fluid does not need to be replaced by refilling and the life of the collector is extended due to the lower thermal stress.

a fulfilled another purpose the protective screen, when viewed from the sun, swung behind the vacuum tube becomes. He then reflects the solar radiation on the sides the vacuum tube radiated to the vacuum tube and increases that way the amount of radiation that falls on the vacuum tube. This will increase the efficiency of the collector, especially for high temperature applications. There are fewer vacuum tubes necessary, to collect the same amount of energy. This also means that less material is used and the energetic payback period is reduced.

It there is a tendency for collector fields with higher coverages. That means the collector surface will be in relation to to the required heat requirement designed larger. In the winter half-year and in the transitional period can be such a bigger part the heat requirement be covered. In such a design but then enters the overheating problem especially in the summer more often on.

Also There is a tendency for solar collectors to have a higher temperature for the Provide consumers. This is for example for solar cooling and for process heat applications required. At such high temperatures proves the protective screen as particularly useful. At high Temperatures, the standstill problem is exacerbated because the solar collector is already working close to the temperature limit.

at higher Temperatures of the heat transfer fluid makes the invention a higher efficiency of the collector noticeable. Through the reflective inside of the protective screen the collecting radiation area is increased. This improves The relationship of loss area to collecting surface, so that the thermal losses of the collector are reduced.

According to a preferred embodiment of the invention, a plurality of vacuum tubes are arranged parallel to each other at mutual distances, each vacuum tube having a protective screen. The shields are coupled together by a common drive, so that the shields are adjusted synchronously. This allows large-scale solar panels with high energy gain overheating safely realized.

Of the Protective screen can be powered by a motorized drive from the temperature of the absorber tube or the liquid flowing therein be automatically adjusted.

in the Embodiments will be described below with reference to the drawings closer to the invention explained.

It demonstrate:

1 a perspective view of a solar collector according to the present invention with the protective screen in the first position,

2 the solar collector 1 with the protective screen in the second position,

3 a perspective view of a simple paraboloidal reflector,

4 a perspective view of a reflector consisting of several parabolic sections reflector,

5 an end view of the reflector after 4 .

6 a view of a collector having a plurality of parallel vacuum tubes, from above, and

7 a section through the collector after 6 , but without representation of the drive.

The collector in the 1 and 2 is shown schematically, has an elongated double-walled vacuum tube 10 from two coaxial glass tubes 10a . 10b on, of which the inner glass tube 10b on its outside an absorbent coating 10c wearing. The space between the glass pipes 10a . l0b is evacuated. The inner glass tube 10b , which forms the absorber, is in heat-conducting contact with a Wärmeleitblech 20 that transfers the heat to a heat exchanger 11 emits. The heat exchanger 11 has a running branch 11a and a returning branch 11b on. The branches 11a . 11b are connected by a pipe bend (not shown) also from the vacuum tube 10 is enclosed. They are traversed by a fluid that dissipates the absorbed heat. The vacuum tube 10 is closed at one end by a floor; at the opposite end are the branches 11a . 11b the heat exchanger from the vacuum tube 10 out. The vacuum tube 10 forms a vacuum-tight container that is evacuated to provide good thermal insulation for the heat exchanger 11 to build. In this way it prevents the heat exchanger 11 gives off heat by convection.

Parallel to the vacuum tube 10 is an elongated protective screen 12 provided, which is parabolic or similar bent, wherein the vacuum tube is located in the concave portion of the protective screen. The protective screen forms in the in

1 a shadowed roof which shields the vacuum tube against the incident from above solar radiation. The first position is taken when overheating of the heat transfer fluid is imminent, ie when the temperature of the heat transfer fluid or the absorber tube exceeds a limit.

2 shows the vacuum tube 10 with the longitudinal protective screen 12 which is pivoted to the second position P2 relative to the vacuum tube. The second position is diametrically opposite the first position. The protective screen 12 carries on its inside a reflective layer 13 For example, a Metallevampfung or a metallic foil or a sheet. He forms a concentrator, the solar radiation, which is incident along a broad strip, on the absorber tube l0b focused. The solar radiation passing by the vacuum tube is absorbed by the reflective layer 13 reflected to a large extent on the vacuum tube.

Moving the protective screen 12 between the first and second positions is by a pivoting mechanism (not shown). In this case, the protective screen is pivoted about an axis extending parallel to the vacuum tube axis.

The second position can also be varied according to the respective position of the sun, so that the protective screen 12 In the unshielded operation of the solar collector is constantly tracking the height of the sun and thereby directs as much solar energy as possible on the absorber tube.

The protective screen 12 can have different shapes. In 3 is a parabolic or otherwise shaped protective screen 12a in a perspective view, viewed from an end face, shown. The protective screen forms an elongated channel of paraboloidal or other shaped cross-section, wherein on the inside of the reflective layer 13 located.

The 4 and 5 show a protective screen 12b made up of two different rounded sections 14 . 15 which exists by a longitudinal vertices 16 are connected. It shows 4 a perspective front view and 5 a front view. Such a protective screen is referred to as CPC (Compound Parabolic Concentrator).

In the 6 and 7 a solar collector is shown having a plurality of spaced apart parallel vacuum tubes 10 having. The one end 20 Every vacuum tube comes with a common collector 21 connected. The other end 22 the vacuum tube 10 is closed. In the vacuum tube 10 runs the heat exchanger 11 whose branches 11a . 11b through a pipe bend 11c near the closed end 22 are connected. The branch 11a is to a supply line 24 and the branch 11b to a return line 25 of the collector 21 connected. The collector has an inlet nozzle at one end 26 and a return pipe 27 for the heat transfer fluid. The vacuum tubes 10 can also be connected serially.

Every vacuum tube 10 is a protective screen 12 assigned. The shields are arranged with the shortest possible distances, so that they essentially fill the entire area, which faces the sun. Possibly also distances between the mirrors are advantageous. Each of the protective screens 12 is pivotable about the associated vacuum tube, with a common drive 28 is provided for synchronous adjustment of all the protective screens. The drive 28 has an electric motor 29 on, who pivots the shields together.

One correctly tracked parabolic reflector reflects geometrically the entire direct Radiation on the absorber. The diffused radiation only becomes one Part reflected on the absorber. A tracked CPC reflector reflects part of the direct and diffuse radiation on the absorber.

Of the Protective screen can also be used in an existing construction of evacuated tube collectors to get integrated. In existing collectors, the vacuum tubes are relatively close together. It can every second or several vacuum tubes be removed, leaving room for the protective screen is created. The axis of rotation of the protective screen can with the longitudinal axis the vacuum tube coincide.

Next the application for heat recovery and for hot water, there is another area of application the invention in solar cooling, at the solar heat from the vacuum tube collectors is used to drive a thermally driven chiller. General can a vacuum tube collector provided with protective screens also used for process heat generation be or drive a heat engine that has one Generator can generate electricity.

Claims (6)

Solar collector with one in a vacuum tube ( 10 ) absorber tube ( 11 ), characterized in that a protective screen ( 12 ) provided around the vacuum tube ( 10 ) is pivotable between a first position (P1), in which it shields the vacuum tube against solar radiation, and a second position (P2), in which it exposes the vacuum tube of the solar radiation. Solar collector according to claim 1, characterized in that the protective screen ( 12 ) at its the vacuum tube ( 10 ) facing inside a reflective layer ( 13 ) and in the second position (P2) the solar radiation on the vacuum tube ( 10 ). Solar collector according to claim 1 or 2, characterized in that the protective screen ( 12 ) is generally parabolic curved. Solar collector according to claim 3, characterized in that the protective screen ( 12b ) a plurality of parabolic curved sections ( 14 . 15 ) having. Solar collector according to one of claims 1 to 4, characterized in that a plurality of vacuum tubes ( 10 ) are arranged parallel to each other at mutual distances, each vacuum tube a protective screen ( 12 ), and that the protective screens ( 12 ) by a common drive ( 28 ) are coupled together, so that the protective screens are adjusted synchronously. Solar collector according to one of claims 1 to 5, characterized in that the protective screen ( 12 ) by a mechanical drive ( 29 ) as a function of the temperature of the absorber tube ( 11 ) or the liquid flowing therein is adjusted.