阅读说明：本技术 具有热量存储能力的太阳能烹饪设备 (Solar cooking apparatus with heat storage capability ) 是由 E·索阿尔 于 2019-02-20 设计创作，主要内容包括：本发明涉及一种烹饪设备,该烹饪设备包括：容器(1),其具有包围容器(1)的第一内室(2)的底壁(1a)、侧壁(1b)和上壁(1c),其中容器(1)的底壁(1a)和侧壁(1b)是隔热的,且上壁(1c)除了热传导的至少一个平坦的且基本水平定向的烹饪区(4)之外是隔热的；第一相变材料(8),其位于容器(1)的第一内室(2)内部且基本充满容器(1)的第一内室(2)；电阻加热元件(9),其位于第一相变材料(8)中且电连接到电能源；以及可释放盖(7),其由适于覆盖至少一个烹饪区(4)中的每个且使至少一个烹饪区(4)中的每个隔热的隔热材料制成。(The present invention relates to a cooking apparatus, comprising: a container (1) having a bottom wall (1a), a side wall (1b) and an upper wall (1c) enclosing a first internal chamber (2) of the container (1), wherein the bottom wall (1a) and the side wall (1b) of the container (1) are thermally insulated and the upper wall (1c) is thermally insulated except for at least one flat and substantially horizontally oriented cooking zone (4) that is thermally conductive; a first phase change material (8) located inside the first inner chamber (2) of the container (1) and substantially filling the first inner chamber (2) of the container (1); a resistive heating element (9) located in the first phase change material (8) and electrically connected to a source of electrical energy; and a releasable cover (7) made of a heat insulating material adapted to cover and insulate each of the at least one cooking zone (4).)

1. A cooking apparatus, comprising:

-a first liquid-tight container (1) having a bottom wall (1a), a side wall (1b) and an upper wall (1c) enclosing a first inner chamber (2) of the container, wherein:

-said upper wall (1c) comprises at least one substantially horizontally oriented cooking zone (4) made of heat-conducting material, and

-said bottom wall (1a), said side walls (1b) and said upper wall (1c) except for at least one cooking zone (4) comprise a first thermal insulation (3), and

-a first phase change material (8) located inside the first inner chamber (2) of the first container (1) and substantially filling the first inner chamber (2) of the first container (1),

-one or more resistive heating elements (9) electrically connected to a source of electrical energy and in thermal contact with the phase change material, and

-a releasable cover (7) made of a heat insulating material adapted to cover and insulate each of said at least one cooking zone (4).

2. The cooking apparatus according to claim 1, wherein the first phase change material (8) is a compound or a mixture of compounds that undergoes a reversible phase change allowing to absorb or release latent heat at a temperature in the range of 80 to 500 ℃, preferably 90 to 450 ℃, more preferably 100 to 400 ℃, and most preferably 110 to 300 ℃, preferably a phase change material of more than 100 kJ/kg.

3. Cooking apparatus according to claim 1 or 2, characterized in that the first phase change material (8) is:

-a compound or mixture of compounds selected from the group consisting of: LiNO₃、NaNO₃、NaNO₂、MgCl₂∙6H₂O、NaOH、KOH、KNO₃Or-a mixture of any one:

26.8% by weight of NaCl and NaOH,

7.2% by weight of Na₂CO₃And a combination of NaOH and water,

5% by weight of NaNO₃And a combination of NaOH and water,

49% by weight of LiNO₃And NaNO₃Or is or

31.9% by weight of ZnCl and KCl.

4. Cooking apparatus according to claim 1 or 2, characterized in that the first phase change material (8) is:

-a compound or mixture of compounds selected from the group consisting of: erythritol, acetanilide, pentaerythritol, pentaglycerol, d-mannitol or diethylene glycol/galactitol,

-or a mixture of Pentaerythritol (PE), Trimethylolethane (TME) and neopentyl glycol (NPG) in mole%: 30PE, 10 TME and 60 NPG; 45PE, 45 TME and 10 NPG; 45PE, 10 TME and 45 NPG; or 70 PE, 15 TME and 15 NPG.

5. Cooking apparatus according to any one of the preceding claims, characterized in that the cooking zone (4) has an upper flat surface (5) and is made of:

-a metallic material selected from the group of: fe. Cu, Al, Zn, Sn, W, or

-an alloy selected from the group of: bronze, brass, constantan, steel, bronze, or

-a ceramic selected from the group consisting of: alumina, crystalline silica, porcelain, or heat-resistant glass.

6. Cooking apparatus according to any one of the preceding claims, characterized in that:

-the bottom wall (1a), the side walls (1b) and the upper wall (1c) of the first container (1) consist of a single layer of material selected from the group consisting of: glass, polymer, steel or aluminium, and

-the bottom wall (1a), the side walls (1b) and the upper wall (1c) of the first container (1) have, on their outer sides facing the surroundings of the apparatus, an insulating layer (3) with a thickness of 5 to 30cm, and wherein the insulating layer (3) is made of one or more insulating materials selected from the group consisting of: calcium silicate, porous glass, fiberglass, mineral wool, rock wool, ceramic foam, polyurethane and foamed polyurethane, or other porous materials having air-filled pores.

7. Cooking apparatus according to any of claims 1-5,

-the thermal insulation of the first container (1) is obtained by having the bottom wall (1a), side walls (1b) and upper wall (1c) of the first container (1) formed by at least two concentric similarly shaped containers, wherein the inner container is the first container (1) and one or more outer containers are of larger dimensions so that there is a gap between the inner and second containers and finally the second and third concentric containers, etc.;

-said at least two concentric similarly shaped containers are made of the same or different materials selected from the group consisting of: glass, polymer or metal such as steel or aluminium, and

-the gap between two adjacent second concentric similarly shaped containers is filled with:

-an insulating material selected from the group consisting of: calcium silicate, honeycomb glass, glass fiber, mineral wool, rock wool, ceramic foam, polyurethane and foamed polyurethane, or

-evacuating the gas to a pressure of less than 25kPa, preferably less than 1 kPa.

8. The cooking apparatus according to any one of the preceding claims, characterized in that it comprises two or more insulating layers (6) which enclose the first container (1) except at the areas defining one or more cooking zones (4).

9. The cooking apparatus according to any one of the preceding claims, wherein the source of electrical energy is one or a combination of photovoltaic panels, windmills and grid power.

10. Cooking apparatus according to any of the preceding claims,

-said apparatus further comprises one or more elongated members (11) extending a distance down from said cooking zone (4) into said first inner chamber (2), and wherein

-said elongated element (11) is made of the same material as said cooking zone (4) or of a solid-solid phase change material having a phase transition temperature higher than said first phase change material.

11. The cooking apparatus according to any one of claims 1-9, wherein the apparatus further comprises one or more elongated members (11) extending downwardly a distance from the upper wall (1c) into the first interior chamber (2), and wherein the elongated members (11) are hollow and filled with a second phase change material.

12. The cooking apparatus according to any one of the preceding claims, characterized in that it further comprises a second inner chamber (12), said second inner chamber (12) being located inside said first container directly below and in contact with said cooking zone (4) or said upper wall (1c), and said second inner chamber (12) being filled with a second phase change material (13) which exhibits a liquid-solid phase change and has a lower phase transition temperature than said first phase change material (8).

13. Cooking apparatus according to claim 12, characterised in that the second inner chamber (12) is designed as a metal box or cylinder attached and sealed to the lower surface of the cooking zone (4) and/or to the lower surface of the upper wall (1 c).

14. The cooking apparatus according to any one of the preceding claims, characterized in that it further comprises at least one expansion chamber (20), inside the inner space (2) of the container (1), comprising:

-an inner cylindrical symmetric space, which is limited by a cylindrical side wall (21), a first end wall (22) and a second end wall (23), wherein the first end wall (22) and the second end wall (23) are located at opposite ends of the cylindrical side wall (21),

-an opening (24) in the second end wall (23), and

-a slidable piston (25) located inside and dividing the inner cylindrical symmetry space into a first inner expansion chamber (26) and a second inner expansion chamber (27), and the first inner expansion chamber (26) is filled with a pressurized gas such that it seeks to press the slidable piston (25) towards the opening (24).

15. Cooking apparatus according to claim 14, characterised in that said at least one expansion chamber (20) is located inside the first internal chamber (2) of the container (1) and its opening (24) places the expansion chamber (20) in fluid communication with the first phase change material (8).

16. The cooking apparatus according to claim 14, wherein the at least one expansion chamber (20) is located inside the second inner chamber (12) and its opening (24) places the expansion chamber (20) in fluid communication with the second phase change material (13).

17. The cooking apparatus according to claim 14, wherein the at least one expansion chamber (20) is located in an upper portion of the first inner chamber (2) such that an opening (24) of the expansion chamber (20) is in direct contact with the phase change material (8, 13) and extends through the upper wall (1c) and at least partially into the thermally insulating layer (3), preferably through the thermally insulating layer (3) and a distance into the second thermally insulating layer (6).

18. Cooking apparatus according to any of the preceding claims, characterized in that the cooking zone (4) has a flat upper surface and a thickness such that it protrudes a distance down into the first inner chamber (2), and wherein the first inner chamber (2) has a zone (14) filled with a gas having a pressure varying in the range of 0.25 to 3 bar, more preferably 0.4 to 2 bar, and the zone (14) is defined by a wall 1b), a wall 1c) and the outer surface of the cooking zone (4) at the upper part of the first inner chamber (2).

19. The cooking apparatus according to claim 18, wherein the cooking zone (4) has a lower outer surface shaped convex and rotationally symmetrical with respect to an axis located in the center of the cooking zone (4) and perpendicular to the flat upper surface (5).

20. Cooking device according to any of the preceding claims 1-18, characterized in that the upper wall (1c) forms an enclosure of the upper end of the container (1) and is given a convex-like convex shape protruding downwards into the first inner chamber (2), and wherein the lower part of the cooking zone (4) is given a complementary shape and size to form a tight fit with the convex-shaped part of the upper wall (1 c).

21. The cooking apparatus according to any one of the preceding claims, characterized in that it further comprises an electric heating element (15) in thermal contact with the cooking zone (4) and electrically connected to a source for electric energy.

22. Cooking apparatus according to any of the preceding claims, characterized in that the first container (1) and/or the second inner chamber (12) are made of a flexible material, such that a volume change of all or part of the one or more phase change materials is facilitated by a similar change in volume of the first container (1) and/or the second inner chamber (12).

23. The cooking apparatus according to any one of the preceding claims, wherein the cooking apparatus further comprises a second phase change material encapsulated in small micro-containers/capsules dispersed in the first phase change material, and wherein the second phase change material in the micro-containers/capsules has a higher phase change temperature than the surrounding first phase change material.

24. The cooking apparatus of claim 10, wherein:

-the first container (1) is filled with pentaerythritol as a first PCM material and is made of aluminium, and wherein the first container is shaped as:

i) a rectangular parallelepiped with an internal length in the range of 20 to 50cm, preferably 30cm, an internal width in the range of 20 to 50cm, preferably 30cm, and an internal height in the range of 12 to 50cm, preferably 15cm, or

ii) a cylinder with an internal diameter in the range of 20 to 50cm, preferably 30cm, and an internal height in the range of 10 to 40cm, preferably 15cm,

and wherein the cooking apparatus comprises in the range of 20 to 70, preferably 30 to 70, elongated members (11) made of aluminium, and wherein:

-said elongated members (11) are adapted to fit inside said inner chamber (2) when projecting downwards from said cooking zone (4) and arranged in parallel and at a distance from each other, preferably evenly spaced from each other,

-the elongated member (11) has a thickness in the range of 0.5 to 3mm, preferably 1.0 to 1.5mm, and

-said elongated member (11) extends down into said inner chamber (2) for a distance in the range of 2 to 40cm, preferably 5 to 20cm, above said bottom wall (1 a).

25. Cooking apparatus according to any of the preceding claims, characterized in that the cooking zone (4) further comprises a lifting mechanism adapted to be fully embedded and retracted into the cooking zone (4) in a first position and further adapted to extend a distance above the upper surface of the cooking zone (4) in at least a second position.

26. The cooking apparatus of claim 25, wherein the lifting mechanism

Or:

-comprises a set of rod members (30) which, in a first position, are fully embedded and retracted into recesses in the upper surface of the cooking zone (4); and is

-wherein each lever part (30) is pivotally attached at one end to a lever (31) extending from the lever part (30) and extending a distance outside the cooking apparatus, and thus allowing one end of the lever part (30) to rise upwards from its recess in the cooking zone (4) and to protrude a distance above the upper surface (5) of the cooking zone (4) by twisting the lever (31),

or:

-comprising a set of toothed bar members (30) located in said cooking zone (4) and vertically oriented and vertically displaceable between a first position in which said toothed bar members (30) are fully embedded and retracted into said cooking zone (4) and at least one second position in which said toothed bar members (30) protrude a distance above an upper surface (5) of said cooking zone (4) by means of a pinion attached to a rod (31) extending from said toothed bar members (30) and extending a distance outside said cooking apparatus.

27. Cooking device according to any of the previous claims 10-26, characterized in that the cooking zone (4) and the fins (11) are made simultaneously by extrusion of aluminium.

Technical Field

The present invention relates to a photovoltaic-driven cookware with heat storage capability.

Background

Over 10 billion people live around the world in areas where grid power is not available. Over 20 million people do not receive clean cooking techniques and cook food on open fire with a lack or lack of smoke emissions. Continued exposure to combustion gases is a serious environmental and health concern. Thus, there is a need for a cooking capability that is less expensive and does not depend on burning matches, coal or other combustion fuels as an energy supply.

Almost all people who do not get clean cooking have good sun exposure conditions, making sunlight a rich and available energy source.

Disclosure of Invention

The main object of the present invention is to provide a low cost and reliable solar and optionally net electric powered cooking apparatus with heat storage capability suitable for areas where the power grid power cannot be reliably provided everyday.

Drawings

FIG. 1a is a cross-sectional view taken along the dashed line labeled B-B' in FIG. 1B, schematically illustrating an exemplary embodiment of the invention.

FIG. 1b is a cross-sectional view taken along the dashed line labeled A-A' in FIG. 1a, schematically illustrating the same exemplary embodiment of the present invention as shown in FIG. 1 a.

Fig. 2 is a similar cross-sectional view as shown in fig. 1a of a second exemplary embodiment of the present invention.

Fig. 3 is a similar cross-sectional view as shown in fig. 1a of a third exemplary embodiment of the present invention.

Fig. 4 is a similar cross-sectional view as shown in fig. 1a of a fourth exemplary embodiment of the present invention.

Fig. 5 is a similar cross-sectional view as shown in fig. 1a of a fifth exemplary embodiment of the present invention.

Fig. 6 is a similar cross-sectional view as shown in fig. 1a of a sixth exemplary embodiment of the present invention.

Fig. 7a) to 7c) are schematic diagrams of exemplary embodiments of a lifting mechanism for adjusting the rate of heat transfer from a cooking area to a cooking tool.

Fig. 8a) to 8c) are schematic views of an eighth exemplary embodiment of the present invention.

Fig. 9 is a schematic diagram of another exemplary embodiment of the present invention.

FIG. 10 is a reproduction of FIG. 3 from Panwar et al [4], showing the state of the art of solar cooking.

Detailed Description

The present invention will be explained in more detail by way of exemplary embodiments.

First exemplary embodiment of the invention

A first exemplary embodiment of the present invention is schematically illustrated in fig. 1a and 1 b. Fig. 1a is a cross-sectional view from one side taken along the dashed line labeled B-B 'in fig. 1B, while fig. 1B is a cross-sectional view from above taken along the upper dashed line labeled a-a'.

The first container of this exemplary embodiment is shaped as a vertically upright cylinder with an inner diameter D and an inner height H. The cylindrical container (1) is formed by a cylindrical section (1b) which is closed at the bottom by a disk-shaped bottom (1 a). The annular disc (1c) constitutes the top of the cylindrical container and has a concentric circular opening in which the circular disc (4) constituting the cooking zone is located and forms a fluid seal with the annular disc (1 c). The disc (4) is made of a heat conducting material, such as, for example, an aluminium alloy, steel or the like. For example, the bottom (1a), the cylindrical section (1b) and the annular disc (1c) may be made of thin steel or a polymer shell, for example 1mm thick. A first layer of insulation material (3) is applied to the outside of the bottom (1a), the cylindrical section (1b) and the annular disc (1 c). The material of the first insulation (3) may be rock wool, for example. When not used for cooking food, the cooking zone (4) is covered/closed by a cover (7) made of insulating material.

The interior of the container is filled with a phase change material (8), which may be, for example, NaOH and 7.2% by weight Na₂CO₃Based on the total weight of the mixture. The phase change material may also be mixed with a liquid to allow efficient heat transfer inside the vessel when the main portion of the phase change material is in the solid state.

A resistive heating element (9) is placed in the phase change material (8) and near the bottom (1a) to heat the phase change material above its phase change temperature (which in this exemplary embodiment is 283 ℃). In this exemplary embodiment, the resistive heating element (9) may advantageously be shaped as a flat plate or as a cross of plates fixed vertically in the center of the cylinder (1) and at a distance above the bottom (1a), and may advantageously be equipped with electrical conductors (not shown) that electrically connect the element to an appliance plug socket (not shown) for allowing electrical energy to be supplied to the heating element.

The cooking apparatus may advantageously further comprise an optional temperature sensor (10) located in the phase change material (8), which predetermined temperature may be set, for example, to 300 deg.c in this exemplary embodiment (and naturally at another temperature if another phase change material is applied) when the temperature of the phase change material reaches the predetermined temperature, terminating the supply of electrical energy to the heating element (9). The phase change material (8) may exhibit a solid-solid phase change or a liquid-solid phase change.

The exemplary embodiment also includes a second thermal shield (6) covering the first thermal shield (3). The second thermal insulation (6) is optional but may advantageously be made of a rigid solid material such as, for example, cellular concrete or other foamed ceramic material to provide enhanced container thermal insulation and load bearing capability for the cooking apparatus, allowing it to be used without any additional load bearing or mechanically stable structure. It can simply be placed on the floor and used directly to cook the food (after heating the phase change material). This exemplary embodiment has a particularly simple construction, allowing a particularly low-cost manufacturing of the cooking apparatus. Note that the insulating wall may be comprised of one or more layers of insulating material, as different materials may be cost effective at different temperatures.

Second exemplary embodiment of the invention

As shown in fig. 2, a second exemplary embodiment of the present invention is similar to the first exemplary embodiment except that in order to alleviate the potential problem of the gradual deterioration of thermal contact between the cooking zones (4) (because the phase change material directly below the cooking zone (4) cools due to heat transfer to the food being cooked), there is one or more elongated members (11) extending downwardly from the cooking zone (4) into a substantial portion of the first interior chamber (2) to act as heat conduction bridges to transfer heat from the lower layer and hence the hotter phase change material (8) to the cooking zone (4). This exemplary embodiment has the following advantages: when applying a phase change material exhibiting a solid-solid phase change or a liquid-solid phase change, a relatively high heat transfer period to the cooking zone is allowed to be extended compared to the exemplary embodiment shown in the first example.

The elongated member (11) may advantageously be made of the same metal/material as the cooking zone (4) and may be shaped as an elongated fin, a round bar or the like.

Third exemplary embodiment of the invention

As shown in fig. 3, a third exemplary embodiment of the invention is similar to the first exemplary embodiment except that it further comprises a second internal chamber (12), which second internal chamber (12) is located inside the container directly below and in contact with the cooking zone (4). The second interior chamber (12) is filled with a second phase change material (13) that exhibits a liquid-solid phase change at a lower phase transition temperature than the first phase change material (8) filling the remainder of the first interior chamber (2).

The second inner chamber (12) may advantageously be formed by a metal box/cylinder or the like attached and sealed to the lower surface of the cooking zone (4) such that there is no exchange/leakage of phase change material between the first inner chamber (2) and the second inner chamber (12).

An advantage of this exemplary embodiment is that it is ensured that the phase change material (13) in contact with the cooking zone (4) is in a liquid state until a substantial part of the material (8) has changed phase and thus that an efficient convective heat transfer from the phase change material (8, 13) to the cooking zone (4) is ensured as long as the first phase change material (8) is still at least partly in the high temperature phase. I.e. the user does not empty the thermal reservoir of the first phase change material (8) to such an extent that most of the first phase change material is converted into its low temperature phase. This embodiment thus gives the user a longer time available for high power use.

Fourth exemplary embodiment of the invention

The fourth exemplary embodiment of the invention shown in fig. 4 is similar to the third exemplary embodiment, except that it further comprises a plurality of one or more elongated members (11) similar to those in example 2.

The elongated member (11) may advantageously extend through the second inner chamber (12) and further into the first inner chamber (2) a distance allowing for improved thermal contact between the phase change material inside the first inner chamber and the phase change material inside the second inner chamber. In another embodiment, the component (11) can also be installed only below the second interior chamber (12).

Fifth exemplary embodiment of the invention

The fifth exemplary embodiment of the invention, shown in fig. 5, is similar to the first exemplary embodiment, with the difference that the upper wall (1c) is disc-shaped and forms the upper enclosure of the cylindrical container (1), the cooking zone (4) is placed on the upper wall (1c) and in thermal contact therewith, and it applies a heating element designed as a cross of two plates, and furthermore it comprises an expansion chamber (20) located in the inner space of the container (1) of the cooking apparatus.

The expansion chamber (20) comprises an inner cylindrical symmetric space defined by a cylindrical side wall (21), a first end wall (22) and a second end wall (23) having an opening (24). The first end wall (22) and the second end wall (23) are located at opposite ends of the cylindrical side wall (21). A slidable piston (25) is located inside the inner cylindrical symmetry space and divides the inner cylindrical symmetry space into a first inner expansion chamber (26) and a second inner expansion chamber (27). The first inner expansion chamber (26) is filled with a pressurized gas such that it constantly seeks to press the slidable piston (25) towards the opening (24) and thus to extrude out the phase change material present in the second inner expansion chamber (27).

Sixth exemplary embodiment of the invention

The sixth exemplary embodiment of the invention is similar to the fifth exemplary embodiment, except that the expansion chamber (20) with its location in the upper part of the first inner chamber (2) extends through the annular disc (1c) and at least partly into the first insulator (3), and the second insulator (6), if present, has an opening (24) of the expansion chamber (20) in direct contact with the phase change material (8). The liquid phase-change material may then move up and down within the expansion chamber (20) during expansion and contraction, and no piston (25) is required.

In this design it is desirable to use the phase change material (8) which has the lowest density in the liquid state, and then advantageously a small electrical resistance heater located within the expansion chamber (20) and extending down to the main heating element (9) so that when heat is added to the chamber (2) and expansion begins, the liquid phase change material in the first vessel (2) is in direct contact with the liquid in the expansion chamber (20).

Seventh exemplary embodiment of the invention

The seventh exemplary embodiment of the invention shown in fig. 6 is similar to the fourth exemplary embodiment except that it further comprises a similar expansion chamber (20) as described in the fifth exemplary embodiment, which is in fluid communication with the second phase change material (13) within the second interior chamber (12).

Eighth exemplary embodiment of the invention

An eighth exemplary embodiment of the invention has a cooking zone (4) with a flat upper surface (5) and a thickness such that it protrudes a distance downwards into the first inner chamber (2), as schematically shown in fig. 8 a).

Alternatively, the cooking zone (4) may be given a convex shape at its lower part and be rotationally symmetric about an axis located in the center of the cooking zone (4) and perpendicular to the lines marked a-a 'and B-B' in fig. 1a) and 1B), respectively (i.e. the axis is perpendicular to the upper flat surface (5), as schematically shown in fig. 8B).

Since the portion of (4) protrudes a distance into the first inner chamber (2), a zone (14) limited by the portions of walls 1b) and 1c) and the cooking zone (4) will be formed at the upper part of the first inner chamber (2). This zone (14) can be used as an expansion chamber by filling with a medium pressurized gas such as, for example, 0.25 to 3 bar, preferably 0.4 to 2 bar. Due to its compressibility, the gas-filled zone (14) will absorb a volume change in the liquid-phase change material (8). In another alternative, as schematically shown in fig. 8c), the upper part of the container (1) is shaped like the bottom of a champagne bottle, i.e. the upper wall (1c) forms a closure of the upper end of the container (1), but has a convex protrusion projecting downwards into the first inner chamber (2). The protrusion may advantageously be rotationally symmetrical about an axis located in the center of the cooking zone (4) and perpendicular to the upper flat surface (5). The lower part of the cooking zone (4) should be given a complementary shape and size to form a tight fit with the convex shaped part of the upper wall (1 c).

In all aspects of the invention and in each of the exemplary embodiments described herein, a cooking zone (4) and a gas-filled zone (14) having lower portions projecting slightly into the first interior chamber (2) may be applied.

Ninth exemplary embodiment of the invention

A ninth exemplary embodiment of the present invention applies an elongated member similar to the second exemplary embodiment except that the elongated member is made of a solid-solid phase change material having a phase transition temperature higher than that of the first phase change material. The elongated members may for example be plates suspended or mounted vertically below the cooking plate such that they have a large vertical surface in direct contact with the first phase change material and such that they may stimulate convection of the liquid in the first phase change material when they release heat due to a solid-solid phase change.

Tenth exemplary embodiment of the invention

A tenth exemplary embodiment of the present invention applies a flexible material on the walls of the first container (1) and/or the second interior chamber (12) such that all or part of the volume change in the one or more phase change materials is facilitated by a similar change in the volume of the first container (1) and/or the second interior chamber (12).

Eleventh exemplary embodiment of the invention

An eleventh exemplary embodiment of the present invention further comprises a second phase change material encapsulated in small micro-containers/capsules dispersed in the first phase change material, and wherein the second phase change material in the micro-containers/capsules has a higher phase transition temperature than the surrounding first phase change material.

The second phase change material encapsulated in small micro-containers/capsules dispersed in the first phase change material is applicable to all aspects of the invention, and is applicable to each of the exemplary embodiments described herein.

Twelfth exemplary embodiment

The twelfth exemplary embodiment of the present invention has a rectangular first container (1) made of aluminum, and its inner size is 30 × 30 × 12cm³Filled with pentaerythritol as a first PCM material, and a set of 50 evenly spaced aluminium fins/elongated members (11) extending downwards from the cooking zone (4) (which may also be made of aluminium) and having dimensions of 0.14 x 10 x 30cm³Such as shown, for example, in fig. 2. The aluminum fins would be spaced between them with a gap of about 4.5 mm.

Calculations show that such a configuration will achieve a heat storage capacity of about 1kWh and allow the cooking zone to be supplied with a heat flux that can be controlled up to about 2kW (with a temperature difference of about 80 ℃ between the phase transition temperature of the cooking zone and the PCM material).

If 30 aluminum fins are used instead of 50 or equal, the solar cooker will be able to store about 1.5kWh of thermal energy and provide about 1kW of heat flux to the cooking area, even when about half of the phase change material has changed phase. In this case, the gap between the aluminum fins becomes approximately 8 mm.

The twelfth exemplary embodiment is a particularly low-cost version of the invention and envisages having a cylindrical first container (1) with an internal diameter in the range 20 to 50cm, preferably 30cm, and a height of 10 to 40cm, preferably 15cm, or alternatively a rectangular first container (1) with a length and width of 20 to 50cm, preferably 30cm, and a height of 12 to 50cm, preferably 15 cm. The inner chamber (2) is preferably filled with pentaerythritol as the first PCM material and comprises a set of 20 to 70, preferably 30 to 70, aluminium fins/elongated members (11) arranged in parallel, preferably evenly spaced, at a distance from each other and protruding downwards from the cooking zone (4) at a distance in the range of 2 to 40cm, preferably in the range of 5 to 20cm, above the bottom wall 1(a) of the first container. The thickness of the aluminium fins/elongated members (11) is in the range of 0.5 to 3mm, preferably in the range of 1.0 to 1.5 mm. In an alternative, the aluminium fins/elongate members (11) may be adapted to extend over the length or width of the inner chamber (2), or alternatively, if the inner chamber is a cylinder, from side to side in a horizontal cross-section of the cylinder. That is, the fins will gradually widen toward the central axis of the cylindrical inner chamber, or in the case of a rectangular inner chamber, likewise.

Verification invention

The solar cooker having the cylindrical inner vessel with an inner radius of 10cm and an inner height of 30cm as described in the first exemplary embodiment may contain about 20kg of solid phase NaOH and 7.2% Na₂CO₃Mixing as a phase change material (density of about 2.2 kg/liter) allows about 2kWh to be stored as latent heat in the phase change material. This latent heat will be released from the phase change material at a temperature of 283 ℃.

In the case of using a rock wool layer having a thickness of 10cm (thermal conductivity of 0.06W/mK) as a first insulation layer and a foamed polyurethane layer having a thickness of 10cm as a second insulation layer (thermal conductivity of 0.025W/mK), the container of the solar cooker attains an outer height of 70cm and an outer diameter of 60 cm.

It is believed that the heat flux across the bottom, bottom surface 2 and upper surfaces 3,4 is nearly equal to the heat flux across the flat composite wall in contact with free-flowing air (natural convection). Such heat fluxes can be calculated by the relational expressions on pages 37 to 38 of [ reference 1 ]:

wherein q' is [ W/m ]²]Heat flux in units of U is [ W/m ]²K]Total heat transfer coefficient in units, T_contIs the temperature in the container]Temperature in units (which is the phase transition temperature of the phase change material), and T_airIs the ambient air at [ deg.C]Is the temperature in units. The total heat transfer coefficient of the composite wall of the digital "i" layer is related by [ reference 1]Pages 37, 38 give:

where L is₁Is the first thermal insulation layer in [ m ]]Is thickness per unit, L₂Is the thickness of the second insulating layer, etc., and k₁Is the first heat-insulating layer with [ W/mK]Thermal conductivity in units, k₂Is the thermal conductivity of the second insulating layer, etc., and h_airIs related to the heat transfer coefficient of natural convection towards ambient air.

H in respect of vertical standing plates_airAbout 5W/m²K (reference [2 ]]). By assuming that the values of the top and bottom surfaces (which will be slightly smaller due to the horizontal orientation of the surfaces) are the same, and that the inner steel shellIs 1mm thick and has a thermal conductivity of 16W/mK (reference [3 ]]) The heat flux across the bottom and top surfaces of the solar cooker vessel became 44.8W/m²Or 1.4W across each of the bottom and top surfaces (if the lid 7 is as thermally insulated from the rest of the wall).

Heat loss through relationship across a cylindrical sidewall of length h (reference [ 1]]Page 40), the side wall having a layered wall structure with a first layer having an outer radius r₁(the layer facing the inner space of the cylinder) and a second layer having an outer radius r₂Etc. until the outer radius of the ith layer is r_air：

Wherein R is_totIs above [ K/W ] on the cylindrical wall]Is the total thermal resistance in units and is defined by:

wherein r is_contIs the inner diameter of the vessel, and A_airIs the outer surface of the cylinder facing the ambient air.

Applying the same wall structure for the cylindrical portion as given above for the bottom and top surfaces, the heat loss across the cylindrical side wall becomes 18.4W, so that the total heat loss generated by the present exemplary embodiment becomes about 21.2W as long as the phase change material releases enough latent heat to maintain the phase change material at 283 ℃. Over a time span of, for example, 24 hours, the exemplary embodiment will lose up to about 0.5kWh of heat when stored indoors (in contact with air under free convection flow conditions). In practice, the heat loss will be slightly less than calculated, because due to the heat loss the phase change material near the vessel wall will gradually solidify and thus increase the thermal resistance across the vessel wall.

About 20kg of NaOH with 7.2% Na₂CO₃This exemplary embodiment mixed as a phase change material can store a latent heat of about 2kWh, such that 24 hours of storageThereafter, about 3/4 of the useful latent heat content of the cookware was retained for cooking food.

Similarly, a cylindrical container having an inner diameter of 15cm and an inner height of 30cm filled with pentaerythritol (IUPAC name; 2, 2-bis (hydroxymethyl) propane-1, 3-diol) as a phase change material can store about 1.8kWh as latent heat (density 1.4 kg/liter, phase change temperature 184.2 ℃ C., and heat of fusion 222.5 kJ/kg). The heat loss over 24 hours of storage became just over 0.4kWh, about 1/4 which is its latent heat content.

These calculations verify that the solar cooker according to the present invention can store and maintain a sufficient amount of heat at a temperature that allows cooking food for at least 24 hours. In subtropical and tropical regions, solar panels with peak power of 300- & ltwbr/& gtw are sufficient to accumulate about 2kWh of thermal energy during one day of sunlight.

It should be noted that the primary mode of use in combination with the PV module would be to add energy during the day, and where most of it is used after 3 hours in the afternoon on the same day. The residual liquid in the phase change material will start to solidify at night along the coldest walls and thereby gradually increase the insulation, so that in many cases 80-90% of the energy added during the day will probably be available for cooking dinner and breakfast/lunch.

The above exemplary embodiments show the cooking apparatus according to the present invention as a vertical cylinder having a single cooking zone. This should not be construed as limiting the invention. The container may alternatively be shaped as a box, i.e. a cuboid of length a, width B and height C, or any other conceivable design, and the cooking apparatus may be provided with two or more cooking zones.

Reference to the literature

1 Adrian Bejan, "Heat Transfer," John Wiley & Sons, 1993.

2 retrieve from the internet: https:// www.engineersedge.com/heat _ transfer/conjugate _ heat _ transfer _ coefficients __13378.htm

3 retrieving from the internet: https:// www.engineeringtoolbox.com/thermal-conductivity-d-429. html

4 Pamwar et al, "State of the art of solar cooking: overview", Renewable and susteable Energy Reviews 16 (2012) 3776-3785, doi:10.1016/j. rser.2012.03.026

5 Lameck NKhonera et al, "Experimental information of a finned regenerative thermal-based heat storage unit for solar cooking at 200 ℃" 200 ℃, "EnergyProcedia, 93 (2016) 160-