DE29820189U1 - Solar cooker - Google Patents

Description

Dr. Volker Zeiler Zeiler 1

Hertlstr. 7
81375 Munich

Solar cooker

The invention relates to a solar cooker.

The state of the art includes the use of the physical principle of the parabolic mirror for cooking and frying food and for producing hot water; the sun's rays generate temperatures of 300 to 750° C at the focal point of such a mirror, depending on the geographical latitude. There are large dry and sunny areas on earth that have, for example, 1500 to 2000 hours of sunshine per year, particularly in northern, western and central China. At least 200 million people live in these areas of China, who have to cook their food with wood etc. every day. However, there is currently too little firewood in these dry areas. Other alternative fuels such as coal, oil and gas are expensive.

Solar cookers whose parabolic mirror surfaces are made up of trapezoidal slats made of high-gloss aluminum are also state-of-the-art. Parabolic mirrors made of glass or facets with foil coverings coated with a mercury layer are also state-of-the-art. Although these well-known solar mirrors appear simple in construction, they have significant disadvantages. High-gloss aluminum sheet is not always available, and is expensive. The aluminum slat arrangement can reduce the utilization of solar radiation by up to 60% due to the abutting flat trapezoidal surfaces. The glass parabolic mirrors are very expensive to manufacture and are also fragile. The foil covering does not offer fully satisfactory reflection properties either due to the edge-shaped transitions at the joints of the facets.

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The object of the invention is therefore to create a significantly simplified structural solution for parabolic mirrors, whereby the utilization rate of solar radiation can be increased to well over 50% to almost 100%. The object of the invention also includes the creation of a significantly simplified structural installation device for the parabolic mirror.

This problem is solved with the features of claims 1 to 11.

The invention is explained in more detail in terms of device in the drawings according to Figures 1 to 4.

Figure 1 shows a sectional view of a parabolic mirror blank T for a solar cooker, which is still in a forming tool 5.

Figure 2 shows a sectional view of the forming tool 5, the extended pressure stamp 6 and the mechanically deep-drawn hard plastic plate.

Figure 3 shows a sectional view of a forming tool 5 and a hard plastic plate deep-drawn by means of vacuum.

Figure 1 shows a sectional view of a parabolic mirror blank T for a solar cooker 1 according to the invention, the paraboloid of revolution 3 of which is formed from a flat, square hard plastic plate 4 in a corresponding forming tool 5. The hard plastic plate 4 has a side length of at least 80 cm, preferably 100 to 380 cm, in particular 140 to 340 cm, and a plate thickness of at least 1 mm, preferably 1.5 to 4 mm, in particular 1.5 to 2.5 mm. The diameter of the parabolic mirror according to the invention is at least 60 cm, preferably 80 to 360 cm, in particular 120 to 320 cm.

Figure 2 shows a sectional view of a forming tool 5, an extended pressure stamp 6 and a mechanically deep-drawn hard plastic plate 4. The hard

plastic plate 4 is secured with the outer edges to the shaping tool 5 by clamping. The shaping tool 5 has the negative spatial shape of the parabolic mirror 2. A pressure stamp 6 that can be lowered into the shaping tool 5 has the positive spatial shape of the parabolic mirror 2. The hard plastic plate 4 is deep-drawn by heating to 60 to 120 ⁰ C and the action of the pressure stamp 6. The shaping tool 5 can additionally have at least two grooves 9 that cross at equal distances in the center of the shaping tool 5. These grooves 9 form the desired number of reinforcing ribs 11 and 12 on the back of the parabolic mirror blank 2' or the parabolic mirror 2 as a result of the heating of the hard plastic plate 4 and the contact pressure of the pressure stamp 6. This embodiment is not shown in the drawing in Figure 2.

Figure 3 shows a sectional view of a shaping tool 5 and a hard plastic plate 4 deep-drawn by means of a vacuum. The hard plastic plate 4 is sealed and secured to the shaping tool 5 by clamping it against the outside atmosphere with its outer edges. The shaping tool 5 has the negative spatial shape of the parabolic mirror 2. The hard plastic plate 4 has an opening 4' in its center, which is connected to a vacuum device 14 via a line 13. The hard plastic plate 4 is deep-drawn in the negative spatial shape of the shaping tool 5 by heating it to 60 to 120 ° C and applying a vacuum. The shaping tool 5 can also have at least two grooves 9 that intersect in the center. As a result of the heating of the hard plastic plate 4 and the suction force of the applied vacuum, the grooves 9 form the desired number of reinforcing ribs 11 and 12 on the back of the parabolic mirror blank T or the parabolic mirror 2. The reinforcing ribs 11 and 12 are therefore produced from the material of the hard plastic plate 4.

According to the embodiments, the parabolic mirror blank 2' remains briefly in the shaping tool 5 so that the dimensional stability of the parabolic mirror 2 is increased by tempering or hardening the deep-drawn hard plastic material. The shaping tools 5 and/or the pressure stamps 6, which are required for the production of parabolic mirror blanks 2' of different sizes, can therefore be heated.

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The dimensional stability of the parabolic mirror 2 can therefore be improved by at least two reinforcing ribs 11 and 12 which are formed on the back of the parabolic mirror blank T or the parabolic mirror 2. For this purpose, at least two grooves 9 which cross each other at equal distances in the center of the base are incorporated in the shaping tool 5. This produces the required number of reinforcing ribs 11 and 12 on the back of the hard plastic plate 4 during deep drawing under pressure applied mechanically or by means of a vacuum. The reflection surface can be spray-coated with mirror-gloss paint or the entire surface of the parabolic mirror blank 2' can be dip-coated with it, preferably anodically or cathodically dip-coated. The paint contains a cross-linking agent which causes the paint to cross-link at elevated temperatures and increases the paint's strength.

The solar cooker 1 according to the invention therefore comprises a parabolic mirror 2 which is deep-drawn from a hard plastic plate 4 and coated with paint. This parabolic mirror 2 is hardened and therefore dimensionally stable. The paint is also thermally cross-linked at elevated temperatures and is therefore very strong. Since the parabolic mirror 2 is made from a square hard plastic plate 4 by deep-drawing, it has parallel side edges even after production. Between the side edges and the beginning of the circular diameter D of the parabolic mirror 2, the hard plastic plate 4 has remained undeformed.

Figure 4 shows a mounting device 20 made of steel or aluminum alloy profiles for the solar cooker 1 according to the invention. The mounting device 20 consists of a rectangular, in particular square, frame 21 which is horizontal in the mounting position and which is made of angle, L, U, I or round profiles and can be set up on the floor with at least three supports 22, which can also consist of these profiles. A rotating plate 23 is arranged on the frame 21, which is preferably circular and is equipped with a sliding, ball or roller bearing. The rotating plate 23 can also be designed as a rotating ring. The rotating plate 23 enables the solar cooker 1 to easily follow the position of the sun 24. Two oppositely arranged, perpendicular

upward-facing supports 25 and 26 made from one of the profiles mentioned, at the upper free ends of which a journal bearing 27 and 28 is provided. The supports 25 and 26 have a length that corresponds to at least half the length or width of the hard plastic plate 4. The journals 29 and 30 are connected to U-shaped rails 31 and 32 that point in the direction of the parabolic mirror 2. The journals 29 and 30 are mounted in the journal bearings 27 and 28.

For reasons of better graphic clarity, the stands 25 and 26, the journal bearings 27 and 28 and the bearing journals 29 and 30 are only shown symbolically in Figure 4. The parabolic mirror 2 is inserted into these rails 31 and 32 with the opposite parallel side edges.

The lower ends of the U-shaped rails 31 and 32 are closed, or the lower ends of the U-shaped rails 31 and 32 are connected to a crossbar 33 made of one of the profiles mentioned, so that the inserted parabolic mirror 2 can rest on it. The system, consisting of the bearing pins 29 and 30, the U-shaped rails 31 and 32 and the parabolic mirror 2 held therein, forms a pivoting device 34. The pivoting device 34 is provided with an overrun brake or locking device (not shown) in order to keep the pivoting device 34 at the required inclination towards the sun. A sundial 35 is attached to one of the U-shaped rails 31 or 32 of the pivoting device 34, so that the inclination of the parabolic mirror 2 can be set and adjusted in an extremely simple manner perpendicular to the position of the sun 24. A support beam 36 is mounted on the U-shaped rails 31 and 32 in the area of the bearing pins 29 and 30. The support beam 36 can be designed as a two-part plug connection. The support beam 36 is mounted on the U-rails 31 and 32 in spring-elastic mounts 40 and 41, which are bent in a hook shape and open at the top. The support beam 36 is to be inserted into these mounts 40 and 41. In the middle of the support beam 36, which is in the area of the focal point 37 of the parabolic mirror 2, there is an insert 38 with an adjustable diameter for holding cooking utensils 39 such as pots, pans, woks, etc. In the setting device 20, the individual parts mentioned are connected by screwing or welding them together.

According to an embodiment of the invention, the diameter D of the parabolic mirror can be 1.6 m. The usable reflection surface according to this example is up to approx. 1.8 m ² . This means that 4 liters of water with an initial temperature of 4 to 12 ° C can be brought to the boil in a suitable cooking pot with a matt black outer surface in a time of 1/2 to ^3/8 hour.

Instead of the hard plastic plate 4, the parabolic mirror blank 2' or the parabolic mirror 2 can be made from metal alloy sheets, preferably from steel or aluminum alloy sheets, with a maximum thickness of 1 mm, preferably from 0.4 to 0.8 mm. These sheets are deep-drawn using the inventive technique and then coated with mirror gloss paint or high-gloss paint.

The solar cooker according to the invention can be used, for example, to effectively and successfully support the state planting program "1 million trees per year" in China. At the same time, expensive fossil fuel can be saved. Furthermore, the solar cooker, which can also be referred to as a solar oven, can be used during non-cooking times to heat dark heat storage material or natural stones, which can be used to heat living rooms and bedrooms. In addition, the production of the solar cooker according to the invention can be largely automated, in particular with regard to the deep-drawing of the hard plastic panels and the coating with mirror-gloss paints.

List of reference symbols:

1 Solar cooker 2 Parabolic mirror 2' Parabolic mirror blank 3 Paraboloid of revolution 4 Hard plastic plate 4' opening 5 Forming tool 6 Printing stamp 7. Turning point 8th Paraboloid 9 Grooves 10 Clamping devices 11 Reinforcing rib 12 Reinforcing rib 13 Line 14 Vacuum device 20 Installation device 21 Frame 22 Support 23 Turntable 24 Sun 25 Stand 26 Stand 27 journal bearing 28 journal bearing 29 Bearing journal 30 Bearing journal 31 rails 32 rails

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• Crossbar .:. 12:. .:. ..'·..' • Swivel device 33 sundial 34 Holding bar 35 Focus 36 Mission 37 Cookware 38 Hook-shaped holder 39 Hook-shaped holder 40 41

Claims (11)

Protection claims: 1. Solar cooker, characterized in that a square hard plastic plate (4) is deep-drawn and hardened in a temperature range of 60 to 120 °C to form a parabolic mirror blank (2') in a forming tool (5) while retaining the square base area, the hardened parabolic mirror blank (2') is converted into a parabolic mirror (2) by spray painting or dip painting with mirror gloss paint, the parabolic mirror (2) is arranged in a mounting device (20) which a rectangular frame (21), a rotating plate (23) arranged thereon, two opposite stands (25) and (26) extending from the rotating plate (23) and pointing upwards at right angles, with a pivoting device (34) into which the parabolic mirror (2) is inserted. 2. Solar cooker according to claim 1,
characterized in that the square hard plastic plate (4) is deep-drawn and hardened in a temperature range of 60 to 120 ⁰ C to form a parabolic mirror blank (2') in a forming tool (5) while maintaining the square base area by means of a pressure stamp (6). 3. Solar cooker according to claim 1,
characterized in that the square hard plastic plate (4) is deep-drawn and hardened in a temperature range of 60 to 120 ⁰ C to form a parabolic mirror blank (2') in a forming tool (5) while maintaining the square base area by means of vacuum. 4. Solar cooker according to claims 1 to 3,
characterized in that the two opposite uprights (25) and (26) extending from the rotating plate (23) and pointing upwards at right angles each have a journal bearing (27) and (28) at the upper ends in which journals (29) and (30) are mounted, the bearing pins (29) and (30) are connected to U-shaped rails (31) and (32) which point in the direction of the parabolic mirror (2), the U-shaped rails (31) and (32) are closed at the lower ends, or the lower U-shaped rails (31) and (32) are connected at the lower ends with a cross member (33), the U-shaped rails (31) and (32) are connected to a support beam (36) in the area of the journal bearings (27) and (28) or the journal bearings (29) and (30), and the support bar (36) has an insert (38) for holding cooking utensils (39) in the region of the focal point (37) of the parabolic mirror (2). 5. Solar cooker according to claims 1 to 4, characterized in that the rotating plate (23) is equipped with a sliding, ball or roller bearing. 6. Solar cooker according to claims 1 to 5, characterized in that the shaping tool (5) is equipped with grooves (9). 7. Solar cooker according to claims 1 to 6, characterized in that a sundial (35) is arranged on one of the U-shaped rails (31) or (32). 8. Solar cooker according to claims 1 to 7, characterized in that the parabolic mirrors (2) with a diameter of at least 60 cm, preferably from 80 to 360 cm, in particular from 120 to 320 cm, are made of flat square hard plastic plates (4) with a side length of at least 80 cm, preferably 100 to 380 cm, in particular 120 to 340 cm, and a plate thickness of at least 1 mm, preferably 1.5 to 4 mm, in particular 1.5 to 2.5 mm. 9. Solar cooker according to claims 1 to 8,
characterized in that the parabolic mirror blank T or the parabolic mirror (2) has at least two intersecting reinforcing ribs (11) and (12) on the back. 10. Solar cooker according to claims 1 to 9,
characterized, that the bearing pins (29) and (30) in conjunction with the U-shaped rails (31) and (32) and the parabolic mirror (2) held therein form the pivoting device (34). 11. Solar cooker according to claims 1 to 10,
characterized, the parabolic mirror blank T or the parabolic mirror (2) is made of metal alloy sheets, in particular of steel or aluminium alloy sheets, with a maximum thickness of 1 mm, preferably from 0.4 mm to 0.8 mm, instead of the hard plastic plate (4).