NL1031766C2 - Energy supply system is constructed by several heat carriers such as pipes, casings and even rod material which issue in under side of concrete case in ground in which thermo convertor is placed - Google Patents

Abstract

The energy supply system is constructed by several heat carriers (8), such as pipes, casings and even rod material, which issue in the under side of a concrete case (18) in the ground, in which a thermo connector is placed. On the under side of the energy carrier fins (9) are provided to enlarge the contact surface. Also, the combination of the earth heat convector, generating nitrogen, and a stationary and mobile convector can produce electrical voltage for a building, activity and road vehicles. The energy supplier is brought into contact with the thermo convertor (14). The concrete case has a cover (16) thermically insulated (19) from the case and in contact with the energy receiver from the upper side of the convertor. Also here is a thermically conductive but electrically non-conductive material can be employed, such as a paste (13). Also the thermo convertor is entirely accessible and its surface (20) can be clad.

Description

Description: Energy supply system The Thermo converter

With a thermo-converter, where two different materials come together at one point (thermo-element) and a temperature difference is made between this point and the other ends, the free valence electrons will flow from the positive metal to the negative metal, so that electrical energy is generated. This is the so-called Seebeck effect.

This effect increases when a second thermo-element is connected in series with the first thermo-element, so that low chains of concatenated thermo-elements are thereby created.

The elements used must be designed in such a way that the electric current is passed through the thermo-element circuit, at the same time the thermal transfer must be limited, and so do not eliminate the temperature difference.

This thenno converter can be used: in combination with geothermal heat, as a stationary facility, mobile in vehicles in combination with liquid nitrogen and as a generator of liquid nitrogen for use by said thermo converters to create an organized temperature difference.

20 thermo converter elements

The main component of this invention is a thermo-converter constructed from metal foils, consisting of, for example, iron constant having a thickness ranging from 0.05 to 0.001 mm.

A constructional shape is preferably a quadrangular foil (1), for instance in the form of a square or a rectangle, wherein the top (2) and bottom beams (3) are the energy absorbers and the center piece contains less material because of the electrical voltage to minimize the thermal compensation between the two beams, as shown in Figure 1.

This configuration can be carried out with holes (4) in the narrow connection strips 30 (4) to control the thermal conductivity.

Another construction has a hole pattern (6) in the middle section between the energy sensors.

These metal foils from, for example, constant and iron are intermittently coupled. In order to increase the desired electrical performance, it is necessary to use these thermo-elements in series, in chains and also in parallel connection.

To prevent a short circuit between the metal foils, an insulator will be installed. The insulation can take place in various ways, such as applying a material as a separating layer, applying an insulating layer to the foil material (7), or by allowing the surface of the plates to oxidize partially and in a controlled manner, for example with magnesium, so that an oxidation layer is formed locally (7), which prevents electrical conduction between the films.

In this invention, in particular, the method of isolation is of great importance, because the thickness of the oxidation layer, for example 0.001 mm, has a small influence on the thickness of the element without an insulator, and thus gives the thermal converter a greater capacity. The insulating layer can be applied to both films of the thermo-element, or one of the films can be partially insulated on both sides (7).

The connection per element is obtained by clamping the majority of the energy sensors.

This thermal converter structure will be used in all cases of this invention. The geothermal heat converter The thermal transfer of the geothermal heat is carried out by means of energy transfer (8), being staff material, or by a tube or tube closed at the bottom, whether or not filled with thermally conductive material, from a depth of, for example, 6 meters to the thermo converter .

To increase the contact surface, fins (9) may be provided on the underside of the energy transfer device. The cross-section of the energy transfer device has a diameter of approximately 50 mm.

The sleeve can consist of several parts.

The last part to the thermal converter will be thermally insulated with an insulator (10) with water-repellent properties, to prevent the temperature from being equalized with the temperature closer to the earth's surface (11).

The energy transfer device is brought into contact with the thermal converter.

A possible design is the application of a flange (12) on the energy carrier (8). To prevent short-circuiting between the flange and the thermal converter, a thermally conductive, but electrically non-conductive material is applied, for example a paste (13).

In another construction form, fitting pieces are fitted, in the event of subsidence, and couplings, stabilizers, stabilizer rubbers, suspension or otherwise are used to absorb vibrations and movements.

35 3

Preferably, the thermal converter (14) is placed in a cabinet made of concrete (18) and is on the inside, covered with a watertight thermal insulation material (15) and provided with a condensation drain.

Furthermore, the cabinet is provided with a cover (16) and thermally insulated (19) from the concrete cabinet and in contact with the energy sensor from the top of the converter. Here, too, a thermally conductive, but electrically non-conductive measure may be used, for example a paste (13).

Furthermore, the thermo converter as a whole is passable and passable. The surface (20) of the thermal converter can be coated.

10

The thermal converter can also be designed as a part of a building, such as a facade, roof, energy profile, lantern, fencing, garden wall, pergola, scaffolding, platform, or for example as part of an insulated building, retention wall, work of art or otherwise.

15

Nitrogen stationary converter.

In order for the thermal converter to supply more energy than with the geothermal thermal converter, a gas, for example nitrogen, is used and is introduced in liquid form (minimum minus 196 degrees Celsius) on one side of the converter, around the energy carrier 20 of the thermal converter. to cool elements.

The liquid nitrogen will absorb heat and transfer to a gaseous phase and then leave the room. The gas is then passed to a compressor, where the gas is compacted and increases in temperature, to be introduced into the other chamber of the thermo-converter to release the heat to the other side of the energy carrier of the thermo-elements .

This can cause a delta T of 300 degrees Kelvin. After the energy has been released, the gas leaves the thermo converter.

Nitrogen mobile thermo-converter 30 The above-mentioned nitrogen thermo-converter can also be applied in vehicles, where in combination with a storage of liquid nitrogen it is made possible to drive the vehicle.

Energy supply system 35 The aim is an energy supply for a building or activity, with an integrated storage tank (17), preferably filled with nitrogen.

4

The previously described ground-based thermal converter (21) generates energy. If more energy is generated than is currently crushed, this surplus can be used, for example, with a machine (22), for example according to the Linde process, whereby nitrogen is extracted from the outside air and compressed in such a way that it becomes liquid and then store.

This liquid nitrogen can be used to supply vehicles equipped with a nitrogen mobile thermo converter (23), but also as a stock for a stationary nitrogen thermo converter (24), which can then again supply energy for the energy requirement of the building or activity ( 25).

In addition, energy can also be fed back to the energy grid (26).

Description Figures Figure 1.

This is a front view of the sheets, in which the strips (5) are visible between the energy sensors (2 and 3), also in the variant with holes in the strips (4) and in which the center piece is provided with holes (6) .

Figure 2.

This is a front view of the sheets, the hatched portion (7) being the insulated portion.

Figure 3.

This is a side view of the thermal converter, which is passable.

Figure 4.

This is a side view of a thermal converter, designed as a structure, such as a wall.

Figure 5.

This is a schematic overview of the energy supply system Figure 6.

This is a section of a fence viewed from above.

Figure 7.

30 This is a section of a wall model viewed from above. The thermal converter can be placed against the wall (27) or wall.

1031766

Claims (46)

A film, characterized in that it is made from a constant material with a thickness ranging from 0.05 to 0.001 mm. 3. A film, characterized in that it is made of steel with a thickness ranging from 0.05 to 0.001 mm. 4. A quadrilateral foil with the characteristic provided on both sides with energy sensors. 5. A round or oval-shaped foil with energy absorbers on both sides. 6. A mono- or polygonal shaped foil with energy absorbers on both sides, not being an H shape. A film according to claim 4, 5 and 6, characterized in that the piece between the energy sensors contains less material. A film according to claim 4, 5, 6 and 7, characterized in that the piece is perforated between the energy sensors. 9. A film according to claim 4, 5, 6 and 7, characterized in that the piece between the energy sensors is provided with a hole. A film according to claim 4, 5, 6 and 7, characterized in that the piece between the energy sensors is provided with holes. II. Thermo elements characterized in that the sheets are provided with insulation 12. Thermo elements according to claim 11, characterized in that the insulation is formed by oxidation with magnesium. Thermoelements according to claim 11, characterized in that the insulation is formed by applying a layer of electrically insulating material 1 03 1 7 66 The thermo-elements according to claim 11, characterized in that the insulation is arranged on both sides of the foil. The thermo-elements according to claim 11, characterized in that the insulation is arranged on one side of each foil. 16. A thermal converter characterized in that an energy transfer device is used to direct the geothermal energy to the thermal converter. 17. An energy transfer device, characterized in that it is formed by staff material 18. An energy transfer device, characterized in that it is formed by a tube or tube closed at the bottom, whether or not filled with thermally conductive material. 19. An energy transfer device having the feature on the underside of fins are provided. 20. An energy transfer device, characterized in that the tube or tube consists of several parts. 21. An energy transfer device, characterized in that the bar material consists of several parts An energy transfer device according to claims 17 and 18, characterized in that the last part to the thermal converter is thermally insulated with insulation material with water-repellent properties. 23. An energy transfer device as claimed in claims 17 and 18, characterized in that the last part to the thermal converter is thermally insulated to prevent the temperature from being equalized with the temperature closer to the earth's surface. An energy transfer device according to claims 17 and 18, characterized in that it is brought into contact with a thermal converter. 25. A thermal converter, characterized in that indirect contact is made with metal energy transmitters, by means of a thermally conductive, but electrically non-conductive material. 26. A thermal converter characterized in that indirect contact is made with metal energy transmitters by means of a thermally conductive but electrically non-conductive paste 27. A thermal converter, characterized in that fitting pieces 5 can be used with the energy transfer device. 28. A thermal converter characterized in that the energy transfer device is provided with couplings, stabilizers, stabilizer rubbers or suspension to absorb vibrations and movements. 29. Thermo-elements, characterized in that the connection is obtained by clamping the energy sensors. 30. A thermal converter with the characteristic that it is placed in a concrete cabinet; A thermal converter according to claim 30, characterized in that the concrete case is covered on the inside with watertight thermal insulation material. 32. A thermal converter according to claim 30 and 31, characterized in that it is provided with a condensation drain. A thermal converter according to claim 30, characterized in that the concrete trough is provided with a thermally insulated cover. A thermal converter according to claims 30 and 33, characterized in that the cover is provided with a thermally conductive, but electrically non-conductive material. A thermal converter according to claims 30 and 33, characterized in that the cover is provided with a thermally conductive, but electrically non-conductive paste. 36. A thermal converter, characterized in that it is passable and passable. 37. A thermal converter, characterized in that the surface can be coated. 38. A thermal converter, characterized in that it can be designed as a part of a building, facade, roof or extension wall. 39. A thermal converter with the feature that it is designed as an outer wall, in the form of construction where two walls are used, and the inner wall is the load-bearing wall. 40. A thermal converter, characterized in that it can be designed as an energy column, lantern, fence, garden wall, pergola, scaffolding, platform or work of art. 41. A thermal converter characterized in that it is used with the use of a gas to create a larger delta T. A thermal converter according to claim 40, characterized in that nitrogen is used in both gaseous and liquid form. A thermal converter according to claim 40, characterized in that nitrogen is introduced in liquid form into a chamber of the converter; 44. A thermal converter according to claim 40, characterized in that nitrogen is compressed in gaseous state and introduced into a chamber of the converter. A thermal converter according to claim 40, 41, 42 and 43, characterized in that it can provide a vehicle with a drive. 46. A thermal converter characterized in that it can generate nitrogen from the ambient air. 47. A thermal converter with the characteristic that it supplies electrical energy to the energy grid. 48. An energy supply system characterized in that it consists of a combination of geothermal heat converter, also nitrogen generator, and nitrogen converter, to meet the electrical needs of building, activity and in combination with the drive of vehicles. 1 03 1 7 66 25