DE3929537A1 - Heat ray reflector for solar cooker - consists of number of flexible discs perforated around edge to form parabola - Google Patents

Abstract

The heat ray reflector is for a solar cooker or similar device. It is made up of a number of individual elements forming a parabolic mirror assembly. The reflective elements (3) are flexible round discs with a series of holes around the perimeter, which overlap each other to receive fixing elements (6, 7, 8). USE/ADVANTAGE - Heat ray reflector for solar cooker can be constructed under primitive conditions with cheap materials which need not be preformed.

Description

The invention relates to a parabolic mirror formed, made up of reflective individual elements heat beam reflector for a solar cooker or the like.

A so-called Bamako mirror cooker (H. Tabor, Solar Energy 10, 153 (1966)).

This type is a stove that was built according to documents from Israel at the Institut de I′energy solaire Bamako / Mali. A tubular steel bracket 1.1 m high and 1.3 m wide can be rotated on a cross. The pot holder is located at the upper end. The reflector can be rotated around a horizontal axis and consists of an arrangement of 12 glass mirrors, each with a diameter of 30 cm. The arrangement of the mirrors is chosen so that the incident radiation is reflected on the underside of the pot. The distance between the pot and the mirror is 83 cm, which is twice the distance from the horizontal axis of rotation. The frame for the mirrors consists of twelve iron rings welded together. The glass mirrors are clamped onto these rings with springs and can be removed for safety. The irradiation opening is 0.81 m ² . The weight of the stove is only 30 kg.

With the industrially manufactured silver glass mirrors, very good focusing is possible, so that temperatures up to 300 ° C can be reached. At 750 W / m ^{2 of} direct insolation, the stove has an effective output of 185 W, which corresponds to an efficiency of 34%. The silver glass mirrors remain relatively clean even when there is a lot of dust, so that the efficiency is not reduced as much as with the reflectors with aluminum foil. Wind affects the cooking performance considerably, but not so much the stability of the device.

The tracking of the mirrors according to the position of the sun is easy. The cook well is accessible for monitoring and tasting at any time. For intensive stirring the stability of the pot holder is hardly sufficient Kocher is easy to transport, especially if the mirror ent are far away.

Welding the iron rings in the correct position requires a lot of skill, otherwise the reflector cooker is quite easy to to build. The mirrors are expensive in Mali and make up about 2/3 of the total Manufacturing price from approx. DM 200, -. Unless the mirror after Use can always be removed, the stove should have a fairly high life have duration.

The disadvantages of the described solar cooker are particularly apparent in Areas of the third world for which this stove is actually intended is. It will be inevitable that the reflecting mirror sooner or later be destroyed from glass. To operate the stove To keep riding must therefore a not inconsiderable stock of glass mirrors to be available.

Welding the rings together is hardly going to take place on the spot leave with the result that previously assembled in the areas of application Stoves have to be transported. Although the arrangement of the saucepan is favorable in the radiation field of the reflectors, the tracking of cumbersome after the sun and only optimally possible if the operator's attention does not wane.

In contrast, the present invention is based on the object to simplify known cookers consisting of individual elements and so  to improve that he price even under the most primitive conditions materials that do not need to be preformed. In particular, it should be achieved that the stability of the above Heat ray reflector and its traceability with respect to the sun guaranteed with simple means and also technically given people can be performed.

This problem is solved in that the reflective individual elements are flexible discs with holes along their edges, which aligning individual holes to accommodate mounting and Partially overlap clamping elements.

Due to the type of overlap and the type of training of the individual It is possible to make any desired size from simple elements Build up the heat radiation reflector and the individual elements as well as the Ge totality of the individual elements into such a tension or curvature bring that any delimitable heating areas (spherical or cylindrical) can be illuminated.

Details and developments of the invention are in the subclaims 1 to 24 marked.

In a preferred embodiment, the reflective is single elements circular discs that have at least 24 holes along their circumference exhibit. The individual elements can be put together so that each Single element curved and open in the manner of its own parabolic mirror the heating area can be aligned. In the heating area a solid metal rod or a metal tube can be used, which also have radially outward-facing heat absorption surfaces are provided. The heat induced in the metal rod can be on itself known way. The metal pipe can be used as a heater Manifolds can be inserted into a heat circuit. As warmth Water or a specially designed carrier is suitable Oil to be kept in stock. It is particularly advantageous if the metal tube or the metal rod through the center of the heat radiation reflector  led out and used to support this reflector.

In a preferred embodiment, the heat beam reflector connected with a standing weight that a ball, a hemisphere or can be a differently shaped body. Without any difficulty the standing weight made of clay, mortar, concrete, metal or other indigenous Manufacture materials. The heat radiation reflector can be strived on Stand weight and / or attached to the metal rod or metal tube.

It is advantageous if the metal rod or the metal tube through the center of the heat radiation reflector protrudes into the standing weight. To one easy tracking of the heat radiation reflector according to the invention To allow sunshine, adjustment rods are provided, which, in the longitudinal direction movable, crosswise through the standing weight. This adjustment rods are so long that you can easily use them to heat the reflector in can spend any desired position.

The invention allows the flexible individual elements of the heat beam reflector made of reflective metal discs, for example consist of aluminum. The radiating side of the individual elements can be polished.

The heat radiation reflector can then be created particularly easily, if the individual elements made of sheet metal, plastic, corrugated cardboard or the like. herge provides and are coated with a reflective film.

As fastening or tensioning elements for joining and tensioning the flexible, reflective individual elements can be fastened with advantage Use tensioning or tensioning screws with nuts. For this, everyone can be arbitrary combination screw / nut are used.

It is particularly easy to assemble and clamp the flexible insert individual elements when pins are used.

The invention allows that any number and any size individual elements can be combined to form a radiation reflector.  

Heat radiation reflectors made of relative are suitable for normal cooking purposes small circular discs, whereas for operation, for example Large individual elements assembled in large numbers by thermal power plants can be.

Weight and size and also the performance of the heat radiation reflector is aimed depending on the materials used.

Of particular advantage is that with few resources, but especially with resources available on site, powerful heat radiation reflectors can be put.

Details of the invention are he based on the drawing purifies. It shows:

Fig. 1 a reflective individual element,

Fig. 2 shows schematically the combination of individual elements according to Fig. 1 to a heat-ray reflector,

Fig. 3 is a heat radiation reflector in connection with a stand weight and

Fig. 4 is a plan view of a special training of the Standge weight.

With simultaneous reference to all of the figures, below is a preferred embodiment of the invention described.

A heat radiation reflector 1 with a center 2 consists of reflective individual elements 3 , which are provided with holes 5 along their edges 4 . In a preferred embodiment, at least 24 holes 5 are provided along the edge 4 of an individual element 3 .

As can be seen in FIG. 2, the individual elements can be placed one above the other in such a way that the holes 5 of adjacent individual elements 3 lie one above the other in such a way that fastening or tensioning screws 6 with nuts 7 or pins 8 can be inserted through the holes. These fastening and tensioning elements are only indicated in FIGS. 3 and 4. Any commercially available individual parts can be used as clamping screws and nuts. Pins 8 are available in any design commercially without having to be explained in connection with the present invention.

According to FIG. 4, the individual elements 3 by means of the fastening or clamping elements, joined together in conjunction with the nuts, but also pins through the plug so that a total of a self-supporting heat-ray reflector 1 of FIG. 3 results. The cohesion between the individual elements 3 can be designed so that not only a heat beam reflector 1 is created, but also using sufficient individual elements a roof, which can be placed on supports or walls if necessary.

Depending on the tension of the fastening or tensioning screws or the pins, a more or less strong parabolic curvature of the heat radiation reflector 1 can be caused. The individual elements 3 themselves are also curved by this joining together and form a parabolic single mirror.

If the individual elements 3 are assembled correctly, the radiation is reflected by them so that an approximately spherical heating region 10 or a cylindrical heating region 11 can be heated. By readjusting the fastening or tensioning screws 6 or the pins, it can be achieved that more or less voluminous heating areas 10 and 11 are irradiated intensively.

That within each heating region 10 or 11 is a heatable metal rod 12 or a heatable metal tube 13 may be arranged FIG. 3 reveals. For the sake of simplicity, item 12 for a heatable metal rod and item 13 for a heatable metal tube are brought up to the black representation in FIG. 3.

In individual cases, either the metal rod 12 or the metal tube 13 are passed through the center 2 of the central element 9 . The end of the metal tube or the metal rod which is passed through can be connected to the heat radiation reflector 1 by means of struts 19 in order to ensure a secure connection between the rod or tube and the heat radiation reflector 1 .

In a preferred exemplary embodiment, the end of the metal rod 12 or the metal tube 13 which is guided through the center 2 of the heat radiation reflector 1 is seated in a standing weight 16 which is dimensioned such that the heat radiation reflector 1 not only receives good hold thereby, but also in a simple manner can track the sun.

The ends of the struts 19 which are not fastened to the heat radiation reflector can be fastened to the metal tube 13 or to the metal rod 12 , but also to the standing weight 16 . This combination is shown in Fig. 3 as a bracket 15 be.

Within the heating areas 10 and 11 , additional heat-absorbing surfaces 14 can be provided on the metal rod or on the metal tube 13 , which radially protrude from the rod 12 or the tube 13 . This improves the supply of radiant heat to the rod or tube.

In Fig. 3, the standing weight 16 is made of solid 17 . According to Fig. 4 but also a hemisphere shown in plan view 18 can be set.

In order to be able to track the heat radiation reflector well of the sun, adjustment rods 20 are provided which, as can be seen in FIGS . 3 and 4, are guided crosswise by the standing weight 16 . Depending on how far the adjusting rods 20 protrude with their grip ends from the standing weight, the angle of inclination of the heat radiation reflector 1 with respect to the sun is predetermined.

3 connecting elbow 21 are connected to the metal tube 13 shown in FIG. Connected, through which the metal tube in a heat cycle as a heater bar is INSERT. The heat transport medium within the heat cycle can be water, but it can also be a suitable oil.

The standing weight can be made with materials such as clay, cement or concrete that are available in the Third World, for example. Through the openings for the metal tube 13 or for the metal rod 12 and for the adjusting rods 20 can be easily introduced into the standing weight.

Stand weights can also be made without changing anything at the core of the invention Metal or other suitable materials are made.

If necessary, the individual elements 3 can also be produced on site from wood, plastic, sheet metal, even from corrugated cardboard. However, they can just as well consist of alumnium or other materials. If necessary, the sides facing the sun can be glued with reflective foils. Metal elements can be sanded or polished on their side facing the sun.

The size of the heat radiation reflector 1 used in each case depends on the intended use. Should the heat radiation reflector or the like only for heating pots. used, you will come out with a small reflector with few individual elements.

When heating heating systems by means of heatable metal pipes 13 , which can be connected in series and in parallel if necessary, larger heat radiation reflectors with larger individual elements 3 or several individual elements are used.

Weight, size and power of the heat radiation reflectors according to the invention depends on the materials used and the desired use.

List of terms used

1 heat radiation reflector
2 center
3 reflective single element
4 rand
5 holes
6 fastening or tensioning screw
7 mother
8 plug
9 central element
10 heating area spherical
11 Heating area cylindrical
12 heatable metal rod
13 heatable metal pipe
14 heat absorption surface
15 holding device
16 standing weight
17 bullet
18 hemisphere
19 strut
20 adjusting rod
21 manifold

Claims (24)

1. In the manner of a parabolic mirror trained, made up of reflective individual elements heat radiation reflector for a solar cooker or the like, characterized in that the reflective individual elements ( 3 ) are flexible, along their edges ( 4 ) with holes ( 5 ) provided disks, which In the direction of individual holes ( 5 ) for receiving fastening and clamping elements ( 6 , 7 , 8 ) partially overlap. 2. Heat radiation reflector according to claim 1, characterized by a central element ( 9 ) around which the individual elements ( 3 ) are arranged. 3. Heat radiation reflector according to claims 1 or 2, characterized in that the reflective individual elements ( 3 ) are circular disks. 4. Heat radiation reflector according to one of claims 1 to 3, characterized in that each individual reflective element ( 3 ) has at least 24 holes ( 5 ) along its circumference. 5. Heat radiation reflector according to one of claims 1 to 4, characterized in that the circular, reflective individual elements ( 3 ) are assembled so that each individual element ( 3 ) curved in the manner of a parabolic mirror and directed towards a heating area ( 10 , 11 ) is. 6. Heat radiation reflector according to one of claims 1 to 5, characterized in that the heating region ( 10 ) is spherical. 7. Heat radiation reflector according to one of claims 1 to 5, characterized in that the heating area ( 11 ) is cylindrical, and that in the heating area ( 10 , 11 ) either a heatable metal rod ( 12 ) or a heatable metal tube ( 13 ) be found. 8. Heat radiation reflector according to claim 7, characterized in that the metal rod ( 12 ) or the metal tube ( 13 ) with radially outward facing the heat receiving surfaces ( 14 ) is provided. 9. Heat radiation reflector according to one of claims 1 to 8, characterized in that the metal rod ( 12 ) or the metal tube ( 13 ) is also part of a holding device ( 15 ). 10. Heat radiation reflector according to claim 9, characterized in that the metal rod ( 12 ) or the metal tube ( 13 ) is passed through the center ( 2 ) of the heat radiation reflector ( 1 ) and serves to support the heat radiation reflector. 11. Heat radiation reflector according to one or more of the preceding claims, characterized in that the metal tube ( 13 ) is inserted as a heater by means of connection elbows ( 21 ) in a heat circuit. 12. Heat radiation reflector according to one of claims 1 to 11, characterized in that it is connected to a standing weight ( 16 , 17 , 18 ). 13. Heat radiation reflector according to claim 12, characterized in that the standing weight ( 16 ) is a ball ( 17 ). 14. Heat radiation reflector according to claim 12, characterized in that the standing weight ( 16 ) is a hemisphere ( 18 ). 15. Heat radiation reflector according to one of claims 12 to 14, characterized in that the standing weight ( 16 ) consists of clay, mortar, concrete or metal. 16. Heat radiation reflector according to one of claims 1 to 15, characterized in that it is fixed by means of struts ( 19 ) on the standing weight ( 16 ) and / or on the metal rod ( 12 ) or on the metal tube ( 13 ). 17. Heat radiation reflector according to one or more of the preceding claims, characterized in that the metal rod ( 12 ) or the metal tube ( 13 ) through the center ( 2 ) of the heat radiation reflector ( 1 ) protrudes into the standing weight ( 16 ). 18. Heat radiation reflector according to one of claims 12 to 17, characterized by adjusting rods ( 30 ), which are displaceable in the longitudinal direction crosswise through the standing weight ( 16 ). 19. Heat radiation reflector according to one of claims 1 to 18, characterized in that its flexible individual elements ( 3 ) consist of metal discs reflecting on one side. 20. Heat radiation reflector according to claim 19, characterized in that the reflective flexible individual elements ( 3 ) consist of aluminum. 21. Heat radiation reflector according to claim 19, characterized in that the reflecting surfaces of the flexible individual elements ( 3 ) are polished. 22. Heat radiation reflector according to claim 19, characterized in that the flexible individual elements ( 3 ) made of sheet metal. Plastic, corrugated cardboard or the like manufactured and coated with a reflective film. 23. Heat radiation reflector according to claim 1, characterized in that the fastening or clamping elements ( 6 , 7 , 8 ) for assembling and tensioning the flexible reflective individual elements ( 3 ) are Spannschrau ben ( 6 ) with nuts ( 7 ). 24. Heat radiation reflector according to claim 1, characterized in that the fastening and tensioning elements for joining and tensioning the flexi ble reflecting individual elements ( 3 ) are pins ( 8 ).