DE2620976A1 - Energy absorber for solar radiation - using air in cross-flow in a two pass system - Google Patents

Abstract

In a solar energy absorber heat is transferred to an air stream which flows in a two-pass pattern, first across the absorber above a baffle plate and then returning below the same baffle. Used for solar heating systems for buildings. Device provides increased energy collection efficiency, lower air flow with consequent increase in air outlet and reduced noise level.

Description

Energy converter for solar radiation

The invention relates to an energy converter for solar radiation with an absorber as a heat exchanger and a gaseous energy carrier, preferably Air.

Under the designation solar collectors are known devices, absorb the sun's rays, convert them into heat and with the help of an energy carrier transport. A metallic heat exchanger is generally used as the absorber, which transfers the absorbed radiant heat to an energy carrier, for example a Liquid or gas. This energy source can direct the heat store or transport and distribute them.

In an energy converter for solar radiation with a gaseous one Air is generally used as an energy carrier to dissipate the absorbed heat. It is known that the efficiency of such converters is significantly affected by the air flow rate and the temperature difference between the collector temperature and the ambient temperature. The higher the temperature of the absorber, the lower is the efficiency of the converter because the losses are roughly proportional to the difference between the temperature of the heat exchanger and the ambient temperature, i.e. generally the inlet temperature of the air, increase.

Furthermore, the efficiency of the converter is significantly influenced by the air flow rate. The heat exchanger is generally in.einem closed and well insulated System that works with a for Cover pane that is permeable to the sun's rays, for example made of glass or plastic, is provided.

This cover plate is particularly effective when the air flow rate is low through emissions from the absorber and above all through heat conduction from the air Part of the radiated heat.

This heat is given off to the environment and means for the energy converter a loss. The efficiency is thus reduced accordingly.

In a known embodiment of the energy converter are therefore two or more cover plates provided ("polar heating and cooling of buildings" (Phase 0), Vol. 11, Final Report, TRW Systems Group, 5/31/74, from NTIS). In such Converters with double glazing, however, the space between the panes must be airtight be completed, so that the penetration of air moisture and thus the formation condensation is prevented.

An insulating glass pane can also be provided for covering. However, such insulation systems are sensitive to different thermal expansions and therefore not suitable for high temperature differences and, moreover, they are relatively expensive.

The invention is therefore based on the object of an energy converter for solar radiation, even with a relatively small flow rate of the gaseous energy carrier works with high efficiency.

The invention is based on the knowledge that the losses of a converter with a gaseous energy carrier through a special flow guidance of the energy carrier, preferably air, can be significantly reduced.

The stated object is achieved in that a Counterflow through a deflection for the gaseous Energy source is provided. This deflection of the flowing medium is obtained in a simple manner through a deflector plate that is permeable to solar radiation. The baffle is located between the absorber and the one exposed to solar radiation and for this Radiation-permeable housing part of the transducer. The air enters through an inlet opening, flows at the baffle, which is heated by slight absorption of the radiation along, is preheated there, deflected at the end of the plate and flows in the opposite direction Direction via the absorber or, in special embodiments, the converter as well through the absorber and then exits again through an outlet opening. By this counterflow of the energy carrier is thus that from the absorber to the baffle plate Dissipated energy is reabsorbed and used with the air flow. she serves to preheat the air and nan therefore receives one even with a low flow rate good efficiency.

A low delivery rate of the energy carrier means a higher outlet temperature and is more valuable and easier to use for various purposes. the lower delivery rate can be required with less effort, for example Fan and the duct size. Since the delivery rate with the delivery rate increases disproportionately, there is also a considerable saving in the amount of material to be fed Drive energy for the promotion, for example the fan drive.

This results in lower investment costs. Furthermore, the promotion large amounts of air are always associated with noise problems and that is why nan is for this reason endeavors to keep the delivery rate small.

To further explain the invention, reference is made to the drawing taken in an embodiment of an energy converter for solar radiation is illustrated schematically according to the invention.

In the figure is an inlet opening for a gaseous energy carrier, preferably air, with 2, an upper flow channel with 4, one The lower flow channel is denoted by 6 and an outlet opening is denoted by 8. Between the upper and lower flow channels 4 and 6, there is one for sun rays transparent baffle 10. The rays of the sun entering the transducer are indicated in the figure by arrows 12. The upper part of the converter housing consists from a cover plate 14 which is permeable to the sun's rays. For example, you can attached to the side walls of the converter housing 18 by means of a profile frame 16, preferably be screwed tight. The converter housing 18 consists at least in part from a good thermal insulation material. To absorb the sun's rays 12, which through the cover plate 14 and the deflection plate 10 can pass through in a simple manner A special paint color on the inner surface of the transducer housing 18 be provided. This color then forms an absorber 20 there.

The air serving as an energy carrier is fed into the inlet opening 8 sucked in and flows over the deflection plate 10, is deflected at the end of the plate and flows in the opposite direction over the absorber 20 and passes through the Outlet opening 8 again, as indicated in the figure by arrows.

The deflection disk 10 and the cover disk 14 can, for example each consist of an approximately 4 mm thick glass plate and so parallel to each other be arranged so that they form a flow channel with a height of a few cm. The end of the deflection plate 10 opposite the inlet opening 2 is located a few cm, preferably about 2 to 3 cm, from the side wall of the housing 18. The two flow channels 4 and 6 are connected to one another through the gap formed there tied together.

Through the warm air and radiation from the absorber surface 20 heats up the deflecting pulley 10. The heat from the deflecting pulley is the greatest Part of the air flowing past in the flow channel 4 and thus the energy carrier fed back. The total heat losses therefore remain even at a high temperature the air exiting at outlet 8 is low. A high outlet temperature means a small delivery rate and nan can therefore also be used in this work area expect high efficiency.

Even with large amounts of air, the heating of this energy source remains low and thus the losses remain with this converter with a simple one Cover plate 14 low and a correspondingly high level of efficiency is obtained.

In the arrangement according to the invention, the moisture is between the two disks 10 and 14 immediately torn with the air flow. Condensation, that could form between the baffle and the cover plate, is with discharged again in the air flow.

Because these two discs are not mechanically firmly connected to each other they can expand essentially freely in the event of large changes in temperature. The risk of destruction at high temperatures is therefore correspondingly low. The frame 16 is expediently dimensioned so that it has the required thermal expansion the cover plate 14 allows.

The embodiment of the energy converter according to the invention has Advantage that the inlet opening 2 and the outlet opening 8 for the energy carrier can be arranged at the same end of the energy converter. The two openings can, for example, on the same face or, as in the exemplary embodiment provided, be provided on different housing surfaces at the same end. Further they can, for example, also be the same on opposing narrow surfaces Be arranged at the end.

The efficiency is up to an air volume of at least 30 m3 / m2h this energy converter is much larger than that Efficiency of the known converter with single glazing. In a working area of around 10 to 20 m3 / m2h this energy converter has a useful power under the same conditions that is approximately 30% higher than the usage performance of the known type of converter.

In Austührungsbeispiel it is assumed that the absorber 20 is only a special embodiment of the inner surface of the housing 18 is used. It however, other known embodiments of absorbers can also be provided be, for example metallic ribs along which the air flows or also overlapping glass plates between which the air flows and a mesh of absorbent material or a porous air-permeable fabric.

3 claims 1 figure L e r s e i t e

Claims (3)

Patent claims 1) Energy converter for solar radiation with an absorber as a 'heat exchanger and a gaseous energy carrier, characterized that a counter flow is provided by a deflection for the gaseous energy carrier is. 2) Energy converter according to claim 1, characterized in that for Deflection of the flowing energy carrier a deflection plate (10) is provided which at least approximately parallel to one exposed to the incident radiation, permeable cover plate (14) is arranged. 3) energy converter according to claim 1 or 2, characterized in that that inlet opening (2) and outlet opening (8) for the energy carrier on the same Are arranged at the end of the energy converter.