DE2720075A1 - Solar hot water or heating system - uses double convex lens to collect and focus rays - Google Patents

Abstract

The solar energy collecting lens acts automatically, according to radiation temperature and local energy requirements. A thermally-controlled storage cell optimally stores the radiation energy using a minimum of exterior energy. The radiation intensifier raises the temp. of a roof covering (10), from which the energy is taken automatically. The complete solar radiation, with the exception of extremely hot days, is utilized giving a balanced temp. level. The temp. of the roof covering is controlled using movable reflective lamellae. Bi-metal springs monitor the temp. of the roof, and control the lamellae.

Description

Wilhelm Emmerich 355o Marburg / L.den 25.4 ·. 77

-Elektromeister- Köhlersgrundgasse

Radiation amplifiers and cell storage

The invention includes an improvement of the heat recovery system, named in the patent application P 262o395.2 With this invention, the temperature level of the solar radiation on the roof cladding of buildings is to be increased, controlled and the energy stored _e A radiation amplifier and a cell storage device that has these properties, can be used, among other things, with great advantage to make the cosmic solar radiation usable for hot water and heating purposes.

When taking advantage of cosmic and solar radiation for hot water and heating purposes there is an interest, to achieve this all year round with the required temperature level. This gives you the advantage of optimal energy generation with minimal external energy input.

The beam amplifier according to the invention works on the principle of a converging lens, the surfaces of which are convex on both sides. Due to the convex profile of the two-sided lens surfaces, a collection of the rays and their bundling is achieved. The bundling of the rays results in an increase in the temperature, preferably on the roof skin. A thermally controllable reflector is proposed to control the temperature supplied to the roof skin. The reflector according to the invention consists of adjustable mirror slats, which can preferably be changed to a closed reflector layer by a mechanical adjustment device. The monitoring of the temperature on the roof skin, and which is guided in the multitubular conduit under the roof skin that of the medium, is preferably done with an _o-tej-one lharejl · bimetallic spring. -2

The bimetal spring is this preferably close to the Roof skin led. The mechanical change in the bimetal spring is used to actuate the laminated reflector utilized.

An exemplary embodiment of the invention is described below with reference to the drawings, FIGS. 1, 2, 3, 4- and 5, which show, in schematic representations not to scale, a radiation amplifier and a cell memory according to the invention. A roof-mounted beam amplifier is shown in Figure 1. The converging lens is denoted by number 1, its convex beam entry surface with 2 and the convex beam exit surface with number 3. The converging lens 1 is held in the frame 4, which is adjustable about the pivot point 11. The pivot point 11 is located in the holder 19, which can be attached to the roof skin AO without changing it. As the converging lens 1 can be adjusted in the directions of the arrows 9, it can be adjusted to the most favorable angle of incidence of the rays. The reflector lamellas are denoted by the number 5 and rotatably mounted on the pins 12 and 13 in the direction of the arrow 2o in the frame 4- thermally adjustable. The thermal adjustment of the reflector lamellas 5 takes place with the bimetallic spring 6, which is attached to the holder 14. The multi-tube line 8, in which the medium that is used to transport energy from the roof area to the point of need, is guided below the roof skin 1o.

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In Pig. 2 the radiation amplifier is in a thermal Phase in which the desired roof skin temperature, as well as that of the medium, in the multi-tube line 8 is not yet is achieved, shown in top and front view. The front view is as a section through the center line 22 shown. In this thermal phase, the bimetal spring 6 is in the position in which it Linkage 7 is not actuated and the reflector blades 5 are at the most favorable angles to the converging lens 1, in which they allow most of the rays 16 to pass without being deflected towards the roof skin 1o. In this position the individual reflector lamellas 5 », the greatest bundling of rays 17 and thus the greatest increase in temperature the roof skin Io reached and taken up by the medium in the multi-tube line 8.

In Fig.3 the beam amplifier is in a thermal Phase in which the desired temperature on the roof skin 1o, as well as the temperature of the medium in the multi-tube Line 8 reached is shown in top and front views. The front view is as a section through the center line 22 is shown. In this thermal phase, the bimetal spring 6 is bent in the direction of arrow 15 and has the linkage 7 movably connected to all of the lamellar reflectors 5 through the brackets 18 are adjusted circularly in the direction of arrow 21. The circular adjustment of the linkage 7 will be the reflector blades 5 around the axes 12 and 13 in the direction of the arrow 2o rotated so that the exiting rays from the converging lens 1 are accordingly deflected and are distributed and the rise in temperature on the roof skin 1c is limited. The roof skin temperature rises however, if it continues to bend, the metal spring will bend 6 even further in the direction of arrow 15 and that The beam 17 is divided even more according to the position of the reflector blades 5. Through the automatic, stepless division of the bundle of chairs 17 gets the same amount of energy with a usable

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Temperature level led to the roof cladding. The temperature level the roof skin is also from the temperature of the medium in the multi-tube line 8 below the roof skin 1o serves to transport the energy to the point of need, influences. Thus it is an automatic Control of the energy radiation to the roof cladding, which is based on the energy requirement, can be achieved.

In Fig.4- the Stilahlen amplifier is in a thermal Phase shown in which the reflector blades 5 by the Bimetal spring 6 are adjusted so that they form a closed reflector layer. The rays that Exit below the converging lens 1, with the reflector layer through the converging lens 1 in the direction of the arrow 23 reflects and limits the temperature of the roof cladding. The complete closure of the lamellar reflector will mainly occur in extreme summer temperatures »

In Fig.5 is a multi-stage, thermally controllable Cell memory shown as an embodiment with eight cells. LIi t the multi-stage controllable cell memory can use the energy, which is preferably taken from the roof covering and used for keißwasser and heating purposes should be made usable, with different temperatures and minimal external energy input, optimally get saved.

The cells of the memory are designated with the consecutive digits 24-31. The energy transport from the roof skin 1o to the cell storage tanks of the numbers 24 to 31 takes place with the medium circuit 88 with the heat exchangers of the numbers 39 to 46 of the multi-tube line 8, the connecting pipes of the numbers M-8 to 61, the pump 71 »the supply line 4-7, and the return line 86 is formed. The medium flow 88 is controlled by the thermostatic valves of the numbers 32 to 38, which are designed as switching valves _; controlled.

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The thermostatic valves of the numbers 32 to 38 are via the capillary tubes of the numbers 72 to 78 corresponding to the sampled values of the capillary tube sensors of the Numbers 62 to 68, which indicate the temperature of the incoming medium flow 88 from the roof cladding to the flow 4-7 sample, controlled. The thermostatic valves are here for example, according to the number of cells, gradually in the temperature range from approx. + 1o ° C to + 8o ° C adjustable.

At a temperature of + 10 ° C of the medium flow 88 in the flow 4-7 »are all thermostatic valves of the numbers 32 to 38 in the direction of the tubes 48.5o 52.54.56.58 and 6o, which lead to the heat exchangers of the current Numbers 39 to 46 lead, open and the medium routes to tubes 49,51,53,55,57,59 and 61 closed. The medium cycle is up to a temperature of approx. + 1o ° C through the thermostatic valve 32, its valve path to the tube 48 is opened and the tube 49 is closed, through the heat exchanger 39 »of the circulation pump 71> of the return 86, the multi-tube line 8 and the forerun 47 formed.

The iaediumstrom 88 of the flow 47 is during this The control phase transfers the energy to the medium of the storage cell 24 via the heat exchanger 39. Exceeds the Temperature of the medium flow 88 + 1o ° G, the thermostatic valve 32 is adjusted by the heat sensor 62 so that that the medium flow 88 through the tube 48 is blocked and released to the tube 49. In this During the control phase, the medium stream 88 flows through the thermostatic valve 33> through the tube 5o, through the heat exchanger 4o and primarily gives its energy here to the medium of the storage cell 25. The medium stream 88 then flows at a lower temperature level through the heat exchanger 39 and via the circulation pump 71 back to the roof skin 1o. The medium flow is corresponding to the different temperature level of the medium flow 88 at the flow 47 88 each to the corresponding heat exchanger

- -er-

of the consecutive digits 39 to 46 and are given to the medium of the storage cell in which the Heat exchanger is located, mainly from the energy. To control the medium flow 88 this is of the Cap ^ illar tube sensors of the consecutive digits 62 to 68 on the flow 47 scanned. At a temperature level of + 70 ° C of the medium flow 88 at the flow 47, all thermostatic valves are adjusted with the number 32 to 38 so that that the medium paths of the tubes 48.5o, 52,54,56,58 and 6o are closed and the medium flow 88 initially flows through the heat exchanger 46 and mainly gives its energy to the medium of the storage cell 31. From here, the medium stream 88 flows through the heat exchanger of the following digits running backwards 45 to 39 and gives up to one to the memory cells Temperature increase of the entire medium of the cell storage to approx. + 9o ° C energy. This is where the medium flow breaks 88 each from the heat exchangers with the descending digits from 46 to 39 with a lower one Temperature off. This ensures that the return 86 to the roof skin 1o by a sufficient temperature gradient to the flow 47 optimally absorbs energy, whereby the energy supply of the roof skin 1o for a short time can be removed and released in the cell storage system. The delivery rate of the circulation pump 71 is by means of the electronic control part 7o continuously changed so, that the flow rate in the multi-tube line 8 is the energy supply from the roof skin 1o adapts. The electronic control part 7o is controlled by the sensor 69, which scans the flow temperature 47 changed so that an optimal temperature level of the medium flow 88 for energy storage is reached. The values that the sensor 69 scans at the flow 47 are sent to the electronic control part? O communicated via the electrical line 87.

The stored energy is preferably used directly and secondarily with a heat pump for hot water and

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Heating purposes made usable · To make the stored energy in the cell storage, the medium flow flows through the flow 89 to the point of demand and Sound here through the return line 9o to the memory cells with the consecutive digits 24 to 31, which are connected to the tubes of the serial numbers 79 to 85 are connected.

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Claims (1)

Claims On the basis of a collecting lens working radiation amplifier with which, among other things, one can expand the usable Cosmic rays and sun rays, preferably for hot water and heating purposes, an increase that is automatic according to the radiation temperature, as well as according to the local energy demand, is achieved. A thermally controllable one Cell storage with which the energy supply of cosmic and solar radiation with minimal external energy input is optimally storable. 2 · radiation amplifier and cell memory according to claim 1 characterized in that the temperature level of the roof skin raised by the radiation amplifier 1o of from which the usable energy for hot water and heating purposes is to be drawn, automatically, without additional External energy, is thermally controllable. 3. radiation amplifier and cell memory according to claim 1 characterized in that solar radiation is excluded on days with extreme solar radiation, the entire energy flow according to Fig. 2 and 3 is approximately balanced Temperature level can be made usable. 4 ·· radiation amplifier and cell memory according to claim 1 characterized in that adjustable mirror slats for controlling the temperature level of the roof skin to be used. 5 · Radiation amplifier and cell memory according to claim 1 characterized in that for sensing the roof skin temperature level and for controlling the mirror blades preferably one or more adjustable bimetal springs are used. 6. radiation amplifier and cell memory according to claim 1, characterized in that the converging lens 1 is pivotable is held in the frame 4- so that a 809845/0386 6 · Adjust according to the direction of arrows 9 in the most favorable Radiation angle of incidence, regardless of the roof pitch, is possible. 7. radiation amplifier and cell memory according to claim 1 characterized in that the radiation amplifier is to be fastened with the holder 19 on the roof skin 1o is without changing the roof skin 1o. 8. radiation amplifier and cell memory according to claim 1, characterized in that the energy supply, which is preferably taken from under the roof skin 1o is with the thermally controlled cell memory shown in Fig.5, which is preferably made of thermally resistant Plastic is made, saved. 9 · Radiation amplifier and cell memory according to claim 1, characterized in that the medium flow 88 with Capillary tube sensors scanned and with thermostatic valves is controlled. 10. Radiation amplifier and cell storage device according to claim 1 characterized in that the cell memory with any number of thermally controllable stages, as well as memory cells is produced. 11. Radiation amplifier and cell memory according to claim 1, characterized in that the delivery rate of the circulating pump 71, which is used to transport the medium from the roof cladding to the point of need, continuously thermally is controllable. By which the flow rate of the medium under the roof skin 1o is adjusted so that a usable temperature level at the flow 47 is maintained with optimal energy transport. 12. Radiation amplifier and cell memory according to claim 1 2,3 » ^z * -» 5> 6 »7,8,9, u.1o characterized in that the roof skin 1o, for energy storage, which this through the radiation amplifier with the larger full volume and Temperature level is executed as a memory - 3 8098A5 / 0386 12. and thus used to compensate for the day to night temperature. 809845/0386