DE2511740A1 - Solar energy collector for house roof - has large number of mirror plates reflecting radiation onto common collector - Google Patents

Abstract

The collector is mounted on a south facing sloping roof. It is built from a large number of rectangular reflecting mirrors (2) which are placed between the roof joists (1). Each mirror is mounted on a lever arm (3) and all the arms are moved together from a motor (4) in unison with the movement of the sun. They are arranged to reflect incident radiation onto a collector tube (7) through which water is circulated. The energy from all the reflectors is concentrated on a single collector which is thus raised to a higher temperature and occupies less space than a collector receiving radiation directly. The tilting of the mirrors ensures that radiation is concentrated on the same spot at all times of day.

Description

RSFLEKORSYST4 FOR GIVING SOLAR ENERGY.

The invention relates to a reflector system for generating solar energy, preferably used for house heating and hot water preparation.

When generating solar energy for heating out and hot water preparation the following requirements must be met: - The energy must be at a temperature level can be obtained from over 80 ° C - energy must be generated all year round, be guaranteed especially in winter.

- The fall arrest devices (here reflector system) must be without essential Impairment of the environment can be installed at the place of energy demand.

Black collector surfaces are known to meet these requirements, which are directly irradiated by the sun, to be installed on the roof surfaces (VDI-Nachrichten of August 23, 1974, page 1). These directly irradiated collectors radiate in spite of a heat-insulating cover with glass or other transparent materials a large part of the collected heat. This will make their effectiveness greatly reduced and it is not possible to mention particularly in the winter months To gain amounts of energy at the desired temperature level. Other possible solutions (Environment 2/74 pages 28 to 32) are either too expensive (solar cells) or too bulky (Parabolic mirror).

The latter disturb the overall picture when used for house heating Settlement and cast additional shadows that affect the neighbors. she must be designed to be stable (and expensive) to absorb the wind forces and are heavy to clean.

The invention is based on the object, on the one hand, of energy yield and to increase the temperature level at times when the sun is low, on the other hand to enable a practical, cheap and environmentally friendly arrangement of the collecting system.

This object is achieved according to the invention in that a number stiff-shaped reflector lamellas. installed parallel to each other in the roof structure, the Solar radiation on a strip-shaped layer lying parallel above the reflector blades Collector area bundles The collector area is compared to the total area the reflector lamellas are small, so that the ones reflected back from the warm collector surface Heat is small compared to the radiated heat. So can excessive heat loss be avoided. The reflector blades are parallel to the longitudinal axis Roof pitch, preferably to the south, they can be tilted in the longitudinal axis, dap the solar radiation as the sun moves from east to west always on the Eollektorfläche is reflected. Changes in the altitude of the sun have an effect characterized in that the reflected, strip-shaped bundle of rays along the longitudinal axis the collector surface is moved. The further the shift, the greater is the distance between the collector surface and the reflector lamella must therefore to utilize the entire reflected radiation at every height of the sun be longer than the reflector blades. The additional collector length requires additional Heat losses. In order to keep the additional collector length small, the distance between the collector surface and the reflector lamellas must be small in relation to the Length of the same.

The reflector lamellas are designed to protect against the effects of the weather (wind load, Snow load. Soiling) according to the invention can be covered with transparent plates. So it is possible to make the reflector blades and their adjustment mechanism weak and cheap to create. In addition, only the outer smooth-surfaced cover is here to clean, which can easily be automated with a mechanical spraying and wiping device is. The transparent cover replaces the usual roof cover with roof tiles or the like.

The reflector blades can be straight or transverse to the longitudinal axis arched in such a way that a focal line is created approximately at the level of the collector surface. In the first case, the individual reflector lamella must be narrower than the collector surface and in the second case it can be wider.

Depending on the direction of the roof waste, the angle of inclination and the time of year the position of the reflector blades required at a certain time of the day changes. Although the exact temporal change of position differs from the daily and yearly course can be calculated exactly for each application is a purely time-controlled regulation the reflector position does not make sense. The control mechanism required for this would have to be adjusted for each new application, it would be complicated and would require intensive maintenance (e.g. readjustment in the event of time deviation, power failure): In addition, he would have higher requirements for compliance with the structural dimensions (roof pitch) and with regard to the freedom from distortion of the roof and reflector structure.

A regulation by direct action of the solar radiation is through prevents the fact that the control is interrupted when the sun is covered. When clearing up, the actual position is so far removed from the target position that a light or heat signal that is sufficient for the control is difficult to determine and it takes a long time to readjust the reflector blades.

The object of the regulation is achieved according to the invention, since a Time control for the approximate adherence to the target position of the reflector blades cares. A higher-level control system, which is steered directly by the solar radiation, regulates the exact position of the reflector blades and adjusts the time control That is, it effects the seasonal adjustment of the time control.

An embodiment of the invention is described below: Fig.l shows a section of a south-sloping roof in which an inventive Reflector system is installed. The reflector blades (2) are between the rafters (1) arranged.

The reflector blades are tilted so that the falling on them Solar radiation is reflected on the tubular collector surface (7) will. The position of the reflector strips shown in Fig. 1 corresponds to that for 9 Clock time of day on the day of the equinox required position. The single ones Reflector blades are connected by a linkage (3) in such a way that a change the Eippstellung only for all reflector blades at the same time by the same amount is possible. The drive (4) tilts the reflector blades with a due to the timing of 715 degrees per hour from the 9 o'clock position to 3 o'clock position.

If the sun shines during this time, the solar radiation will be with the correct position of the reflector blades on the tubular collector surface reflected. Does the position of the reflector blades change due to seasonal factors Influences, or due to inaccuracies in the timing of the correct position falls, the reflected radiation falls on one of the two sensors (9 and 10). Depending on which sensor the radiation falls on, the drive is set forwards or backwards until both sensors deliver the same signals. Will such a Adjustment between 11.55 a.m. and 12.05 p.m. is necessary for me, so the Time control adjusted, so that the new position at the same time of the following Day is reached again. When the 3 o'clock position is reached, the reflector blades are Tilted back to the 9 o'clock position. The one attached to the collector surface heats up The temperature sensor (11) is activated by the incident solar radiation, so cooling water becomes sent through the collector pipe (7). If the temperature sensor cools down 900C, the cooling water is switched off and the pipe system empties again. Emptying the pipe system prevents freezing in cold spells. The water heated up by the collector pipe is stored and used when there is a need for heat cooled in the heating devices of the house. The transparent cover (5) protects the reflector blades from the elements.

Fig. 2 shows a house with a sloping roof with 3 sections in the roof are installed according to Fig.l. The collector pipes (7) are held by supports (8}, Via which the cooling water is also supplied and discharged. The beam path ¢ for the extreme The positions of the sun for the year are entered for 50 ° north latitude. When changing the The position of the sun between these extreme positions shifts the point of incidence of radiation from (12) to (13). The distance between (12) and (13) is small compared to the total length of the collector pipe. The collector pipe must be longer than that by this distance Reflector blades.

Claims (7)

Claims. 1. Reflector system for the generation of solar energy can be used preferably for house heating and for Warmwas serbereiturgi characterized in that a number strip-shaped reflector blades, tiltable in their longitudinal axis, mainly after The solar radiation is directed south onto a strip-shaped collector surface bundles. 2. reflector system according to claim 1, characterized in that the The longitudinal axis of the reflector blades is mainly oriented to the south-east to south-west are. 3. reflector system according to claim 2, characterized in that the Reflector blades installed in roofs along their longitudinal axis parallel to the roof pitch that slope south-east to south-west. 4. reflector system according to claim 2, characterized in that the Reflector blades are covered with a transparent cover. 5. reflector system according to claim 2, characterized in that the The distance between the collector surface and the reflector blades is small compared to the length the same. 6. reflector system according to claim 2, characterized in that the Control of the reflector blades via a time-dependent control and via a Superordinate control directed by the solar radiation is accomplished. 7. reflector system according to claim 6, characterized in that the time-dependent control adjusted by the control directed by the solar radiation will.