CZ27596U1 - Magnetic heater with cooling medium - Google Patents

Description

Technical field

The proposed technical solution falls within the field of heat generation by means of an electromagnetic induction device.

Background Art

The famous principle found by Nikola Tesla can be used to produce heat. The essence of this is that a permanent magnet moving near the diamagnetic material induces eddy currents that heat the diamagnetic material. Diamagnetic materials include, for example, copper, carbon, bismuth, sulfur, or gold.

Said principle of controlled heating is utilized by the apparatus described, for example, in U.S. Pat. No. 2,912,552. A device for heating foodstuffs is described herein. The device comprises a rotating permanent magnet carrier, wherein the carrier surface, respectively, of the magnet. magnets, overlaps with a diamagnetic material piece. The carrier is directly connected to the rotation source via the shaft. The diamagnetic material panel is here in the form of a cooker plate on which a heated food can be placed.

Another device is disclosed in U.S. Pat. No. 3,187,151. It is again a food heating device. It operates on the same principle as the apparatus described in U.S. Pat. No. 2,912,552, and its construction is rather solved with respect to better storage of the heated containers.

US 3 272 956 discloses a device for heating and moving elongated metal parts. The device comprises two opposed rotary permanent magnet carriers with the same axis of rotation. Each carrier is directly connected to the rotation source via the shaft. A space of diamagnetic material is drawn through the space between the carriers. Rotation of the carriers induces eddy currents and heats the metal member.

A magnetic medium heater with cooling medium is described in US 4,614,853. It comprises two rotary permanent magnet carriers mounted on a common shaft which is directly connected to an electric motor. A copper vessel with a cooling medium is placed between the rotary carriers. The vessel is provided with a cooling medium inlet and outlet. In order to increase the efficiency of heat transfer from the vessel to the cooling medium, its inner walls are provided with the cooling media extending into the volume of the cooling medium.

Another magnetic media heater with a cooling medium is described in US 6,011,245. It contains a closed vessel with a supply and removal of cooling medium. A tube of non-ferrous metal passes through the container and is sealed in its walls. A magnet is rotatably mounted on the shaft in the tube. The tube is surrounded by a system of copper tubes filled with liquid silicone, the axis of which is parallel to the axis of rotation of the magnet. By rotating the magnet, the copper tubes are heated and the heat is transferred to the cooling medium.

The prior art could be summarized in that the known devices do not use the principle described above sufficiently efficiently. Their imperfect constructions do not allow to fully utilize the energy inserted into the movement of the magnets. The amount of thermal energy obtained is not satisfactory, and the devices exhibit undesired loss of kinetic energy.

The essence of the technical solution

The essence of the technical solution lies in the construction of a magnetic heater with cooling medium. As a rule, the heater is in the form of a boiler for heating smaller objects, but further use can be considered, for example to produce steam for different applications. The heater contains a rotating permanent magnet carrier. It is preferred that the carrier is made of a non-magnetic material. The surface of the carrier and the magnets overlap at least partially with the diamagnetic material member. In particular, the diamagnetic material used is copper, others may be, for example, carbon, bismuth, sulfur, or gold. The diamagnetic material panel is adapted to be at least partially cooled

-1 CZ 27596 Ul. That is, it is directly or indirectly at least partially in contact with the cooling medium. This prevents overheating of the part and at the same time takes over the generated heat for further use. The cooling medium is usually water, which can be supplemented with various additives. An alternative may be, for example, oil, alcohol, etc. The carrier is connected to the source of rotation through the shaft. The source of rotation is usually an electric motor. However, any external torque source can be considered, eg water or windmill.

The shaft passes through the rotary carrier and is firmly attached to it. The shaft is supported on both sides by bearings. This is essential to the self-supporting position of the rotary carrier. As a result, it does not have to be fixedly fixed by the shaft to the rotation source as an overhung rotary carrier. This makes it possible to connect the shaft to the source of rotation by means of a starting coupling. The starting clutch may be a variator. This is advantageous for easier starting of the whole device, as the magnets in conjunction with the diamagnetic material exhibit high starting resistance. The diamagnetic material panel is located on both sides of the rotary carrier magnets. This is achieved by either using multiple parts or by molding the panel to surround magnets on both sides. This achieves optimum device efficiency. It is convenient if the magnets are oriented so that their polarity is alternating. This brings even greater efficiency.

In a preferred embodiment, the diamagnetic material panel is in the form of a plate with at least one coolant duct. In this case, the plate is provided with a cooling medium inlet and outlet that passes through the channel.

In another preferred embodiment, the diamagnetic material member is in the form of at least one coolant tube. The tubes can be placed in parallel and almost in close contact. Then it is a solution similar to the above described board solution, but it is cheaper to produce. Alternatively, the tube may be spiral-shaped, almost all over the surface of the rotary support. This is useful for maximizing the potential of the rotary carrier. On the contrary, thanks to the rotational shape of the spiral, deaf spots are eliminated, where the magnets do not move during the diamagnetic part, which saves the diamagnetic material compared to eg the rectangular plate.

In another preferred embodiment, the diamagnetic material member is at least partially immersed in the cooling medium. In this case, an expansion vessel with a cooling medium is used in which the panel is at least partially situated. The expansion vessel is provided with a coolant inlet and outlet.

In a further preferred embodiment, the diamagnetic material member is directly in the form of a container provided with a supply and outlet of cooling medium. Such a solution is very compact and has a relatively low weight.

Very preferred is an embodiment wherein the rotary support is a pot-shaped. With their longitudinal axis, the magnets are located radially, i.e. perpendicular to the axis of rotation of the carrier, on the free peripheral portion of the carrier. A corresponding circular groove is formed in the diamagnetic material member, in which a free peripheral portion with magnets is inserted. The shaft is located in the center of the circular groove.

Clarifying drawings

An exemplary embodiment of the proposed solution is described with reference to the drawings in which Figure 1 is a plan view of an embodiment of a diamagnetic material heater in the form of container walls;

FIG. 2 is a front view of an embodiment of a diamagnetic material heater in the form of vessel walls partially immersed in the cooling medium;

Fig. 3 is a side elevational view of an embodiment of a diamagnetic material heater in the form of cooling medium containers;

FIG. 4 is a front view of an embodiment of a diamagnetic material heater in the form of cooling medium containers;

Fig. 5 is a side view of an embodiment of a diamagnetic material heater in the form of tubes formed in a spiral shape and seated in holders;

Fig. 6 is a front view of an embodiment of a diamagnetic material heater in the form of tubes formed into a spiral and seated in the holders;

Fig. 7 is a side elevational view of an embodiment of a diamagnetic material heater provided with a circular groove in which a free peripheral portion of a rotary pot-shaped carrier is mounted on which magnets are attached;

FIG. 8 is a front view of an embodiment of a diamagnetic material heater provided with an annular groove in which a free circumferential portion of a rotary pot-shaped carrier is mounted on which magnets are attached;

Fig. 9 is a side view of an embodiment of a diamagnetic material heater in the form of a plate with at least one coolant duct;

FIG. 10 is a sectional view taken along line A-A of a heater with a diamagnetic material panel in the form of a plate with at least one coolant duct.

Examples of technical solutions

Example 1

An exemplary embodiment of a magnetic medium heater with a cooling medium comprises a rotary carrier 7 of the permanent magnets 10. The surface of the carrier 7, respectively. magnets 10, partially overlap with the diamagnetic material member 9. Diamagnetic material is copper here. The diamagnetic material panel 9 is adapted to be cooled by a cooling medium. The carrier 7 is connected via a shaft 5 to a rotational source I in the form of an electric motor attached to the holder 2.

The shaft 5 extends through the rotary carrier 7 and is supported on both sides in bearings 4. The shaft 5 is connected to the rotational source 1 by means of a starting clutch 3.

The diamagnetic material panel 9 is located on both sides of the magnets 10 of the rotary support 7.

The diamagnetic material sections 9 are partially submerged in the cooling medium or in the cooling medium. it forms one of the walls of the vessel 8 provided with the inlet 11 and the outlet 6 of the cooling medium.

An exemplary embodiment is shown in Figures 1 and 2.

Example 2

An exemplary embodiment of a magnetic medium heater with a cooling medium according to this example differs from Example 1 in the construction of diamagnetic material panels 9. Each of the diamagnetic material panels 9 is here in the form of a vessel 8 with a Π inlet. and outlet 6 of the heated coolant. The diamagnetic material panels 9 are spaced apart by spacers 18. The bearings 4 are supported in the holders 16 and the entire heater rests on the base plate 17.

An exemplary embodiment is shown in Figures 3 and 4.

Example 3

An exemplary embodiment of a magnetic medium heater with a cooling medium according to this example differs from Example 1 in the construction of diamagnetic material panels 9. Here, each of the diamagnetic material panels 9 is formed in the form of a tube 13 into a spiral shape and seated in the tube holders 19 and provided with an inlet 11 and a heated cooling medium outlet 6. The tube holders 19 also serve as a bearing holder 16. The tube holders 19 are expanded by a set of spacers 18. The entire heater rests on the base plate 17.

An exemplary embodiment is shown in FIGS. 5 and 6.

-3CZ 27596 Ul

Example 4

An exemplary embodiment of a magnetic medium heater with a cooling medium according to this example differs from Example 1 in the construction of the diamagnetic material component 9 and the shape of the rotating permanent magnet carrier 7. In the previous examples, the rotary carrier 7 of the permanent magnets 10 was disc-shaped and the axis of the permanent magnets 10 was consistent. with the shaft rotation axis

5. Here, the cup-shaped rotary support 7 and the permanent magnets 10 are located on its free circumferential portion 14 by its longitudinal axis, i.e. perpendicular to the axis of rotation of the carrier 7. The corresponding circular groove 15 is made in the diamagnetic material part 9, in which a free peripheral portion 14 of the rotary carrier 7 is mounted with the magnets 10. The shaft 5 with one bearing 4 is located in the center of the annular groove 15 in the diamagnetic material part 9, the second bearing 4 is supported on the holder 16. The diamagnetic material part 9 here forms one from the walls of the cooling medium vessel 8 provided with the inlet H and the outlet 6 of the cooling medium. The vessel 8 is provided with an inlet H and a coolant outlet 6. The entire heater rests on the base plate 17.

This solution is very light and compact, and at the same time brings very high efficiency. In addition, a relatively small amount of diamagnetic material in the panel 9 is needed for its construction. both sides of the magnets 10 on the rotary support 7.

An exemplary embodiment is shown in Figures 7 and 8.

Example 5

An exemplary embodiment of a magnetic medium heater with a cooling medium according to this example differs from Example 1 in the construction of diamagnetic material panels 9. Each of the diamagnetic material panels 9 is here in the form of a plate with a channel 12 for conducting the cooling medium. Diamagnetic material panels 9 are provided with a Π inlet. and the coolant outlet 6 and are spaced apart by spacers 18. The bearings 4 with the shaft 5 are housed therein in the holders 16. The entire heater rests on the base plate 17.

An exemplary embodiment is shown in FIGS. 9 and 10.

Claims (7)

PROTECTION REQUIREMENTS A magnetic coolant heater comprising a rotary carrier (7) of permanent magnets (10), wherein the surface of the carrier (7), respectively. The magnets (10) overlap at least partially with a piece (9) of diamagnetic material which is adapted to at least partially cool the cooling medium and the support (7) is connected via a shaft (5) to a rotation source (1). The shaft (5) extends through the rotary support (7) and is supported on both sides by bearings (4), wherein the diamagnetic material component (9) is situated on both sides of the magnets (10) of the rotary support (7). Magnetic coolant heater according to claim 1, characterized in that the shaft (5) is connected to the source of rotation (1) by means of a start coupling (3). Magnetic coolant heater according to claim 1 or 2, characterized in that the parts (9) of diamagnetic material are in the form of a plate with at least one channel (12) for guiding the coolant. Magnetic coolant heater according to claim 1 or 2, characterized in that the diamagnetic material components (9) are in the form of at least one coolant tube (13). -4EN 27596 Ul Magnetic heater with cooling medium according to claim 1 or 2, characterized in that the parts (9) of diamagnetic material are at least partially immersed in the cooling medium. Magnetic coolant heater according to claim 1 or 2, characterized in that the parts (9) of diamagnetic material are in the form of a container (8) provided with a coolant inlet (11) and outlet (6). Magnetic coolant heater according to claim 1 or 2, characterized in that the rotary carrier (7) is pot-shaped, wherein the magnets (10) by their longitudinal axis are located radially to the axis of rotation of the carrier (7) on the free circumferential portion. (14) of the carrier (7), and in the panel (9) of diamagnetic material, a circular groove (15) is formed in which a free circumferential portion (14) with magnets (10) is inserted.