WO2019170511A1 - Induction heating device and method for operating an induction heating device - Google Patents

Abstract

An induction heating device is proposed that comprises at least one coil device (14), wherein the at least one coil device (14) has a plurality of helical windings (28), which are arranged in rows (30) and/or columns (32), wherein the at least one coil device (14) is formed by a tube (16) through which a heat exchange medium can flow.

Description

 Induction heating device and method for operating a

 induction heating

The invention relates to an induction heating device, comprising at least one coil device, wherein the at least one coil device comprises a plurality of spiral windings, which are arranged in rows and / or columns.

The invention further relates to a method for operating an induction heating device.

From DE 10 2013 111 266 A1, a coil device is known, comprising at least one current-carrying high-frequency strand and a carrier for the at least one high-frequency strand, wherein the carrier is a mesh and the at least one high-frequency strand via one or more

Holding threads is held on the mesh.

From DE 20 2015 100 080 Ul an induction heating device is known, comprising a support and a coil device, which is arranged on the support, wherein the coil device comprises a plurality of spiral windings, which are arranged in rows and columns, and where in the spiral Windings are formed so that when current flows through the spiral windings, a current direction in adjacent edge winding sections of adjacent in a row or column spiral windings is at least approximately equal.

The invention has for its object to provide an induction heater of the type mentioned, which has extensive Einsatzmöglich- opportunities. This object is achieved according to the invention in the case of the induction heating device mentioned in the introduction, in that the at least one coil device is formed by a tube through which a heat transfer medium can flow.

The tube for the at least one coil device forms a fluid line and in particular a liquid line in order to be able to flow through the coil device with a heat transfer medium and in particular cooling medium.

Further, the tube forms an electrical line to allow induction heating.

By means of the induction heating device according to the invention, a defined surface area can be specifically heated. The coil device can be cooled by means of the heat transfer medium itself in order to achieve effective heating. If necessary, it is also possible to influence the heating temperature of the induction heating device via the heat transfer medium.

In particular, the tube is made of copper. This way an effective induction heating can be achieved. Furthermore, for example, heat can be effectively dissipated from the coil device.

It is favorable if the at least one coil device has an input connection for heat transfer medium and / or has an output connection for heat transfer medium. It can be so

Coil device with heat transfer medium to flow through, for example, to effect a cooling of the coil device or to influence a heating temperature.

In particular, the at least one coil device also has electrical connections in order to enable just an induction heating, when the coil device is correspondingly electrically applied. An adaptation to surfaces to be heated can be carried out if the at least one coil device with the tube is bend flexible. As a result, the coil device can be adapted to an application and, for example, also curved surfaces can be heated.

In one embodiment, a pump means for conveying heat transfer medium through the at least one coil device is provided. As a result, it is possible to carry out targeted action on the coil device with heat transfer medium. In particular, a conveying speed or a volume flow can also be set.

In one embodiment, a temperature-setting device of heat transfer medium is provided. This adjusting device is positioned in particular spaced from the at least one coil device. For example, it is possible to set a temperature of the heat transfer medium in a targeted manner before it is coupled into the at least one coil device. As a result, a heating temperature for the induction heating can be specifically influenced or adjusted via the heat transfer medium.

It is advantageous if at least one temperature sensor is provided for determining the temperature of the heat transfer medium in order to be able to carry out a defined temperature setting, for example.

It is also favorable if a control and / or regulating device is provided for setting at least one of the following parameters: a temperature of heat transfer medium, a heating temperature of the induction heating device, a conveying speed of heat transfer medium, a delivery volume of heat transfer medium. This results in such extensive application possibilities of the induction heating device with defined setting possibilities. In one embodiment, the tube is made by a 3D printing process. It can thus achieve a defined shape in order to obtain optimized electrical properties (in particular with respect to the heating) and also cooling properties. In its design as a coil device, the tube can be flexurally flexible, for example, in order to enable optimized adaptability to applications even with a curved surface.

It is favorable if the spiral-shaped windings are designed such that, when current flows through the spiral windings, a current direction in adjacent edge winding sections of helical windings adjacent in a row or column is at least approximately the same. Reference is made in this context to DE 20 2015 100 080 Ul.

The corresponding design of the spiral windings ensures that there is no mutual extinction of electromagnetic fields at the intermediate region between adjacent spiral windings. Due to the geometric arrangement of turns of the spiral windings via corresponding arrangement and formation of the edge winding sections, it is ensured that in this intermediate region the current flows on adjacent spiral windings in the same direction and thus field weakening is avoided.

An edge winding section is a section of an outer turn.

For example, in providing a single helical winding, a highly inhomogeneous energy density distribution occurs. By providing a plurality of spiral windings with the embodiment according to the invention, a homogenization of the energy density distribution is obtained during operation when the current flows through, which in turn enables homogeneous heating of components. Relative to the surface of the support, on which spiral windings are arranged, a homogeneous heating can be realized thereby.

The helical windings on the carrier effectively form islands, the islands being wound in such a way that field erasure in the intermediate region between adjacent spiral windings is avoided.

In principle, the corresponding induction heating device can be expanded as desired with respect to the surface.

In particular, it is provided that a first helical winding has a first edge winding section and a second helical winding has a second edge winding section, wherein the first helical winding and the second helical winding are adjacent and wherein the first edge winding section and the second edge winding section portion adjacent, and wherein at current flow, the current direction in the first edge winding section and the second edge winding section is at least approximately equal. As a result, field cancellation is avoided in the intermediate region between the adjacent first spiral-shaped winding and the second spiral-shaped winding. This in turn allows a homogeneous heating of a component, which is heated with the corresponding induction heating device.

For the same reason, it is favorable if at least approximately the same current direction is present in adjacent edge winding sections of neighboring spiral windings both in a row and in a column when current flows through. As a result, field extinction in intermediate regions is avoided in the intermediate regions between adjacent spiral windings on a two-dimensional surface.

It can be provided that adjacent spiral-shaped windings are spaced or overlap, depending on the application. If adjacent helical windings are spaced, then corresponding adjacent edge winding sections are also spaced. If adjacent helical windings overlap one another, then it can be provided that adjacent edge winding sections intersect in a projection onto the carrier.

For a homogeneous energy density distribution, it is favorable if the spiral-shaped windings are arranged with respect to the columns and rows in a two-dimensional grid on the carrier. This makes it possible to achieve homogeneous coverage of the carrier, which in turn makes it possible to achieve a homogeneous energy density distribution.

It is particularly advantageous if the grid is a rectangular grid and advantageously a square grid in order to achieve a homogeneous energy density distribution and thereby homogeneous heatability of a component.

It is favorable if helical windings of at least one identical type are of the same design with respect to an outer envelope. As a result, a high homogeneity can be achieved.

For the same reason, it is favorable if helical windings of at least one of the same type are formed identically with regard to the number of windings.

It has proved favorable if a spiral-shaped winding has at least two turns and in particular at least three turns.

It has also proved to be advantageous to realize a uniform heatability when a spiral winding has at most eight turns and in particular at most seven turns.

It is favorable if the coil device comprises a first type of spiral-shaped windings, in which turns from a starting winding Position away to the outside with increasing distance from the starting point, and include a second type, in which windings to a starting point from outside to inside with decreasing distance to the starting point. The corresponding direction (outward or inward) can be related to the current flow. By providing two different types of spiral windings, it can be realized in a simple manner that the current flow in edge winding sections of adjacent spiral windings has approximately the same direction.

It is particularly advantageous if in the rows and columns spiral-shaped windings of the first type and of the second type are arranged alternately. As a result, it can be achieved in a simple manner that, both in the rows and in the gaps, the edge winding sections of adjacent spiral windings carry a current with at least approximately the same current direction. This in turn avoids field extinction in the corresponding areas.

Conveniently, a direction of rotation of an electric current within a spiral winding is in the same direction and the rotation sense in adjacent spiral windings are opposite. As a result, it can be achieved in a simple manner that adjacent edge winding sections of adjacent spiral windings carry currents whose direction is at least approximately the same.

A helical winding is characterized in that starting from a point (starting point) or an axis, the distance increases or decreases. In principle, this increase or decrease can be monotonous. It is also possible that the corresponding spiral-shaped winding is formed over at least approximately straight turn sections. As a result, the increase or decrease is not monotonous, but there is only an incremental increase or decrease. Such a spiral Winding with straight turn sections can be easily cut down.

It is favorable if adjacent edge winding sections of adjacent spiral windings are oriented at least approximately parallel to one another. It can thereby be achieved in a simple manner that at least approximately the same current direction is present in these adjacent edge winding sections.

It is envisaged that a plurality of spiral windings are electrically connected in series. In particular, adjacent spiral-shaped windings are electrically connected in series. As a result, it can be achieved in a simple manner that the current flow in adjacent edge winding sections has the same current direction.

For example, the spiral windings in a row or in a column are electrically connected in series and, accordingly, rows or columns of spiral windings are electrically connected in series. This results in a meandering course of the current flow with respect to a main current direction.

It can be provided that an electrical connection between adjacent helical windings takes place within a row or column over edge winding sections, or via a connection between exit points for winding of a helical winding. It is thereby possible to connect spiral windings with an "inward orientation" and an "outward orientation". This, in turn, allows different rotational senses for the flow of current within adjacent spiral windings. In turn, this makes it possible in a simple manner to realize at least approximately the same current direction in neighboring edge winding sections of adjacent spiral windings. In particular, within a row or a column, the electrical connection between edge winding sections and exit points alternates. This allows an alternating direction of rotation for the current. It is realized by a homogeneous energy density.

Conveniently, an electrical connection between adjacent rows or columns via an edge winding section and a starting point for turns of adjacent spiral windings takes place. As a result, an electrical connection between adjacent rows or columns can be achieved in a simple manner.

It is favorable if the spiral-shaped windings are designed as flat coils. As a result, a surface induction heating device can be realized in a simple manner.

In one embodiment, the coil device is designed to be self-supporting. It is then not necessarily a support for holding the coil device necessary.

In an alternative or combinatorial embodiment, the coil device is arranged on a carrier.

It is particularly advantageous if the carrier is flexurally flexible and in particular is formed as a mesh and is in particular designed as a textile mesh. It can be done by adapting to heating surfaces and it can, for example, also

curved surfaces and the like are heated.

In one embodiment, the tube is held to the carrier via one or more tethers. As a result, a connection of the carrier to the tube can be obtained in a simple manner. In particular, the combination of tube (the at least one coil device) and carrier can then be flexible in bending. A method is provided for operating an induction heating device according to the invention in which heat transfer medium is conveyed through the tube.

The heat transfer medium may for example serve as a cooling medium in order to be able to dissipate heat from the at least one coil device.

It is also possible for a heating temperature of the induction heating device to be set via the heat transfer medium by passing heat transfer medium through the at least one coil device, for example at a defined temperature level.

This method can be carried out on the induction heating device according to the invention or the induction heating device according to the invention can be operated with this method.

The following description of preferred embodiments is used in connexion with the drawings of further explanation of the invention. Show it :

Figure 1 is a perspective view of an embodiment of an induction heating device according to the invention; and

FIG. 2 shows an illustration of a further embodiment of an induction heating device according to the invention.

An embodiment of an induction heating device according to the invention, which is shown in a top view in FIG. 1 and designated therein by 10, comprises a carrier 12. This carrier 12 is designed as a mesh network. The mesh is, for example, a textile structure, such as a woven or knitted fabric.

The mesh network comprises meshes with webs which are in particular rectangular or square. The webs are made for example by a thread material.

The carrier 12 with the mesh is bendable as a whole.

On the carrier 12, a coil device 14 is arranged. The coil device 14 is formed by a metallic tube 16.

The tube 16 serves to carry a high-frequency alternating current.

It is provided in one embodiment that the coil device 14 is self-supporting with the metallic tube 16. It can then be dispensed with the support 12, or there may be a carrier 12, which facilitates, for example, a fixation of the induction heater to an application.

The coil device 14 is associated with a high-frequency source device 20 (see FIG. 2). During operation of the induction heating device 10, the tube 16 is electrically connected to corresponding terminals 22a, 22b of the high-frequency source device 20.

For this purpose, the tube 16 has a connection 24 at a first end and a connection 26 at a second end.

The high-frequency source device 20 serves to generate a high-frequency electromagnetic alternating field with which the tube 16 is charged. The frequency is at least 20 kHz and is typically around 150 kHz. The high-frequency source device 20 comprises an electronic switching device for generating the corresponding alternating field when the primary electrical source is a DC source.

The coil device 14 comprises a plurality of spiral windings 28. These spiral windings 28 are arranged on the support 12 in rows 30 and columns 32. In order to form a surface induction heating device 10, the spiral windings 28 are arranged uniformly distributed on the carrier 12. The spiral windings 28 are formed on the tube 16.

In particular, the helical windings 28 are arranged through the rows 30 and columns 32 on the carrier 12 in a two-dimensional grid. This two-dimensional grid is in particular a rectangular grid and preferably a square grid.

A respective helical winding 28 has a plurality of turns 34 which are referenced to an exit point 36. An output point 36 lies on a winding axis of the turns 34 of the spiral winding 28. The winding axis is oriented perpendicular to the carrier 12. The spiral of a helical winding 28 is defined as a curve which moves away from the exit point 36 or the winding axis. The distance can be monotonically increasing or the approach can be monotonically decreasing, or it can be increasing or decreasing in sections.

The arrangement of the spiral windings 28 on the carrier 12 determines the temperature distribution on an object to be heated.

The coil device 14 is preferably designed so that a homogeneous field distribution is achieved over the surface of the coil device 14 and, in particular in the region between adjacent spiral-shaped windings 28, a "field cancellation" of the generated magnetic fields is avoided. When current flows through a spiral winding 28, the direction of rotation of the stream flowing through is the same within a spiral winding 28. According to the invention, it is provided that the direction of rotation for the flow of current in adjacent spiral windings 38a, 38b or 40a, 40b is opposite both for rows 30 and for gaps 32.

As a result, the described extinction of the electromagnetic field can be avoided.

The spiral windings 28 of the coil device 14 are electrically connected in series. In the exemplary embodiment shown, the spiral-shaped windings 28 are serially connected in series 30 in a row.

The corresponding rows 30 are in turn connected in series.

The coil device 14 comprises two types of helical windings 28, namely a first type, in which corresponding windings 34 run outward from the respective output point 36 with increasing distance (at least in sections) from the starting point 36. The spiral-shaped windings 38a and 40a are of the first type.

In the helical windings 28 of a second type, the corresponding turns 34 to the exit point 36 run from outside to inside with decreasing distance (at least in sections) from the exit point 36. The spiral windings 38b and 40b are of the second type.

The corresponding winding direction of the first type and the second type is based on the corresponding current flow.

In a row 30, the helical windings 28 of the first type and second type are alternately arranged.

Within a column 32, the first type and second type helical windings 28 are also alternately arranged. As a result, both within a row 30 and within a column 32 with respect to adjacent spiral windings 28, when the current flows through, there is an alternating direction of rotation for the current.

The respective spiral windings 28 have edge winding sections adjacent to the spiral windings. For example, the spiral winding 38a has an edge winding portion 42a adjacent to a corresponding edge winding portion 42b of the spiral winding 38b.

The edge winding sections 42a and 42b are arranged in such a way that, when the current flows through the coil device 14, the current direction in them is at least approximately the same.

This prevents "extinction" of the resulting electromagnetic fields in the corresponding area.

Correspondingly, edge winding sections 44a, 44b of spiral windings 40a, 40b adjacent in a column 32 are arranged so that the current flow in them takes place at least approximately in the same direction.

The arrangement of the edge winding sections 42a, 42b, 44a, 44b is achieved by a corresponding arrangement of helical windings 28 of the first type and of the second type, which is alternating both in the rows 30 and in the gaps 32.

To produce the series connection of the spiral winding 28, 30 adjacent spiral windings 28 are electrically connected to each other within a row. Within a row 30, a first connection type 46 is provided, at which exit points 36 of adjacent spiral windings 28 are interconnected (through a corresponding portion 48 of the pipe 16). In a second type of connection 50, the connection between adjacent helical windings 28 takes place via an edge winding section 52.

Within a row 30, the first connection type 46 and the second connection type 50 alternately follow each other between adjacent spiral windings 28.

For electrical connection between adjacent rows 30, a third electrical connection type 54 is provided. In this case, an electrical connection between a starting point 36 and a Randwicklungs- section 56 takes place.

The spiral windings 28 are arranged as flat coils on the carrier 12 by appropriate shaping of the tube 16.

In one embodiment, the helical windings 28 have straight portions 58. As a result, the spiral winding 28 is not one which monotonically progressively moves away from the corresponding output point 36 or approaches monotonically decreasing. With regard to these sections, however, there is a section-wise removal or approach to the corresponding exit point 36.

In the embodiment of spiral windings 28 with straight sections 58, adjacent edge winding sections 42a, 42b and 44a, 44b are preferably oriented parallel to one another. This results in a parallel current direction there.

In principle, it is possible for adjacent spiral-shaped windings to be spaced apart from one another and for their respective adjacent edge winding sections to be spaced apart from one another. The spiral windings 28 according to the embodiment of Figure 1 are arranged.

It is also possible that adjacent helical windings overlap each other and thereby windings are superimposed. (The tube 16 is thereby isolated to the outside.)

It is possible that edge winding sections, which are adjacent, cross each other (in the projection on the support 12).

Each helical winding 28 of the coil device 14 has a plurality of turns 34. Preferably, each helical winding 28 has at least two and preferably at least three turns 34. It is also favorable if each helical winding 28 has at most eight and preferably at most seven turns 34.

In principle, it is advantageous if the spiral windings 28 of at least the same type are of the same design with regard to the number of turns and the outer envelope surface.

The mesh has a first side 68 and a second side opposite the first side 68. The tube 16 is preferably arranged exclusively or for the most part on the first side 68.

The corresponding winding axes of the spiral windings 28 are transverse and in particular perpendicular to the carrier 12.

The tube 16 is fixed in one embodiment via one or more retaining threads 70 on the support 12 and in particular sewn thereto.

As a result of this fixing via holding threads 70, the winding structure of the coil device 14 on the carrier 12 is also produced. With regard to the fixation via holding threads 70 of the coil device 14 on the mesh network of the carrier 12, reference is made to DE 10 2013 111 266 A1.

With respect to the formation of the coil device is on the

 DE 20 2015 100 080 Ul, to which reference is expressly made.

It can be provided that the coil device 14 is associated with a magnetic flux concentrator layer, which is arranged in particular on that side of the carrier 12 which is remote from the first side 68. Such a magnetic flux concentrator layer, which is made of a material having a corresponding magnetic permeability, serves to concentrate the magnetic flux, which is generated during operation of the coil device 14, in an apron in front of the first side 68.

It is also possible to provide outer electrical insulator layers, between which the carrier 12 with the coil device 14 fixed thereto and, if appropriate, the magnetic flux concentrator layer are arranged. Such outer electrical insulating layers are made, for example, of a silicone material.

The outer electrical insulating layers or the magnetic flux concentrator layer are configured flexibly.

The carrier 12 is flexible. The tube 16 is bendable with the carrier 12. The connection of the tube 16 with the carrier 12 via the or the holding threads 70 allows the bendability.

As mentioned above, the carrier 12 is not absolutely necessary. The tube 16 may be self-supporting and also be bendable alone. In this embodiment, no support 12 is correspondingly present. The induction heating device 10 can be brought into different geometric shapes. For example, a simple curvature or multiple curvature is possible.

The induction heating device is designed as a surface induction heating device in which the arrangement of the spiral windings 28 avoids regions with mutually canceling electromagnetic fields. As a result, homogeneous heating can be achieved with high flexibility.

The spiral windings 28 on the carrier 12 form field-generating islands. Due to the appropriate design of the islands, the "heating surface" can in principle be extended as desired or a size adaptation can be carried out. This is then achieved by appropriate "laying" of the tube 16 on the carrier 12.

The coil device 14 is made of the tube 16 by forming the spiral windings 28. The tube 16 itself is from a

Heat transfer medium can be flowed through. This flow is indicated in Figure 1 by the double arrows with the reference numeral 72. In particular, a liquid such as water is used as the heat transfer medium.

The tube 16 and thus the coil device 14 has for this purpose an input connection 74 for heat transfer medium, and has an output connection 76 for heat transfer medium.

The tube 16 is continuous between the input port 74 and the output port 76. The entire coil device 14 can then flow through the coupling of heat transfer medium at the input connection 74. In particular, the coil device 14 can be cooled by means of heat transfer medium.

By means of the heat transfer medium, a hot temperature of the induction heater 10 can also be adjusted.

The tube 16 is made of copper, for example.

In one embodiment, the tube 16 is made by a 3D printing process.

The tube 16 is preferably formed such that the flexible support 12 also allows for a certain flexural flexibility of the coil device 14 (which is made from the tube 16).

In one embodiment, the induction heating device 10 includes a pumping device 78. This pumping device 78 is connected to the input port 74. About the pump device 74 can be

Transfer heat transfer medium through the tube 16 and thus the Spulenvorrich- device 14 therethrough. In particular, a corresponding delivery speed or a corresponding volume flow of heat transfer medium for passage through the tube 16 can be set or specified via the pump device 78.

In one embodiment, a circuit 80 for the heat transfer medium 72 is provided. In particular, a pipeline 82 is connected to the outlet port 76. This pipeline 82 leads, for example, to a reservoir 84 for heat transfer medium. The reservoir 84 is in particular a source of heat transfer medium for transport through the pipe 16. Alternatively or in addition to the reservoir 84, a cooling device for heat transfer medium 72 (spaced from the coil device 14) may be provided.

An exemplary embodiment of an induction heating device comprises a control and / or regulating device 86. This controls the pump device 78. In particular, a conveying speed or a volume flow of heat transfer medium 72 can be applied via the control and / or regulating device 86 Adjust transport through the pipe 16.

It may be provided that the control and / or regulating device 86 is also signal-effectively coupled to the high-frequency source device 20.

In one embodiment, an adjusting device 88 is connected to the circuit 80, via which the temperature of the heat transfer medium 72 can be adjusted when supplied to the input port 74. In particular, the control and / or regulating device 86 is signal-effectively coupled to the setting device 88 in order to make appropriate settings.

In this case, one or more temperature sensors 90 may be provided which measure the temperature of the heat transfer medium and in particular measure it before being coupled in at the input connection 74.

In principle, the coil device 14 can be cooled during operation of the induction heating device 10 via the tube 16.

It is also possible, in particular if a corresponding temperature of the heat transfer medium for the flow through the pipe 16 is adjusted, to influence the heating effect of the induction heating device 10. In particular, a heating temperature of the induction heating device 10 can thereby be set. The induction heating device 10 according to the invention operates as follows:

The pipe 16 forms both a fluid line (liquid line) and an electrical line for forming the coil device 14. A heat transfer medium 72 can be conveyed through the tube 16 in order to cool the coil device 14 or to set a heating temperature of the induction heating device 10. The flexible design of the tube 16 (with or without carrier 12), which forms the coil device 14, results in an optimized adaptability to specific applications.

For example, it is also possible for a pipe diameter of the pipe 16 and / or a pipe geometry and / or a wall thickness of the pipe 16 to vary over its extent. This results in further possibilities for adaptation. A corresponding variability can be achieved in a relatively simple manner via 3D printing production.

Induction heating device

 carrier

 coil device

 pipe

 High-frequency source devicea connection

b connection

 connection

 connection

 Spiral winding

 line

 column

 convolution

 exit point

a spiral winding

b Spiral winding

a spiral winding

b Spiral winding

a edge winding section

b edge winding section

a edge winding section

b edge winding section

 First connection type

 section

 Second connection type

 Rand winding section

 Third electrical connection type edge winding section

 Straight section

First page tether

Heat transfer medium

input port

output port

pump means

circulation

pipeline

reservoir

Control and / or regulating device adjusting device

temperature sensor

Claims

claims

An induction heating apparatus comprising at least one coil device (14), said at least one coil device (14) comprising a plurality of spiral windings (28) arranged in rows (30) and / or columns (32) characterized in that the at least one coil device (14) is formed by a tube (16) which can be flowed through by a heat transfer medium.

2. Induction heater according to claim 1, characterized in that the tube (16) is made of copper.

3. Induction heating device according to claim 1 or 2, characterized in that the at least one coil device (14) has an input connection (74) for heat transfer medium.

4. Induction heater according to one of the preceding claims, characterized in that the at least one coil device (14) has an output terminal (76) for heat transfer medium up.

5. Induction heater according to one of the preceding claims, characterized in that the at least one coil device (14) electrical connections (24, 26).

6. Induction heater according to one of the preceding claims, characterized in that the at least one coil device (14) with the tube (16) is flexurally flexible.

7. Induction heater according to one of the preceding claims, characterized by a pump device (78) for conveying heat transfer medium through the at least one coil device (14).

8. Induction heater according to one of the preceding claims, characterized by an adjusting device (88) for a temperature of heat transfer medium.

9. induction heating device according to claim 8, characterized by at least one temperature sensor (90) for determining the temperature of the heat transfer medium.

10. Induction heater according to one of the preceding claims, characterized by a control and / or regulating device (86) for adjusting at least one of the following parameters: a temperature of heat transfer medium, a heating temperature of the induction heating device, a conveying speed of heat transfer medium, a delivery volume of heat transfer - medium.

11. Induction heater according to one of the preceding claims, characterized in that the tube (16) is made by a 3D printing process.

12. induction heating device according to one of the preceding claims, characterized in that the spiral windings (28) are formed so that when current flows through the spiral Wicklun- gene (28) a current direction in adjacent edge winding sections (42a, 42b, 44a, 44b) of a series (30) or column (32) adjacent spiral windings (38a, 38b, 40a, 40b) is at least approximately the same.

13. An induction heating apparatus according to claim 12, characterized in that a first spiral winding (38a; 40a) has a first edge winding portion (42a; 44a) and a second spiral winding (38b; 40b) has a second edge winding portion (42b; 44b) wherein the first spiral winding (38a; 40a) and the second spiral winding (38b; 40b) are adjacent and wherein the first edge winding section (42a; 44a) and the second edge winding section (42b; 44b) are adjacent, and wherein Current flow, the current direction in the first edge winding section (42a, 44a) and the second edge winding section (42b, 44b) is at least approximately equal.

14. Induction heating device according to claim 12 or 13, characterized in that in the case of current flow in adjacent edge winding sections (42a, 42b; 44a, 44b) of adjacent spiral windings (38a, 38b, 40a, 40b) both in a row (30 ) as well as in a column (32) at least approximately the same current direction is present.

15. Induction heater according to one of the preceding claims, characterized in that spiral windings (28) of at least one same type with respect to an outer envelope are formed the same, and in particular that spiral-shaped windings (28) of at least one of the same type in number Windings (34) are identical.

16. Induction heating device according to one of the preceding claims, characterized in that a spiral-shaped winding (28) has at least two windings (34) and in particular at least three windings (34), and preferably that a spiral winding (28) at most eight turns (34) and in particular at most seven turns (34).

An induction heating apparatus according to any one of the preceding claims, characterized in that the coil means (14) comprises a first type of helical windings in which turns (34) move outwardly from an exit point (36) with increasing distance from the exit point (36). run, and a second type, in which windings (34) to a starting point (36) outwardly from the outside in with decreasing distance to the exit point (36).

18. Induction heating device according to claim 17, characterized in that in the rows (30) and columns (32) helical windings (28) of the first type and of the second type are arranged alternately.

19. Induction heater according to one of the preceding claims, characterized in that a direction of rotation of an electrical current within a spiral winding (28) is in the same direction and that the rotation sense in adjacent spiral windings (28) are set opposite.

20. Induction heater according to one of the preceding claims, characterized in that spiral-shaped windings (28) are formed by at least approximately straight turn sections (58).

21. Induction heater according to one of the preceding claims, characterized in that adjacent edge winding sections (42a, 42b; 44a, 44b) of adjacent spiral windings (38a, 38b; 44a, 44b) are oriented at least approximately parallel to one another.

22. Induction heating device according to one of the preceding claims, characterized in that a plurality of spiral windings (28) are electrically connected in series, and in particular that the spiral windings (28) in a row (30) or in a column (32 ) are electrically connected in series, and that rows (30) or columns (32) of spiral windings (28) are electrically connected in series.

23. Induction heating device according to one of the preceding claims, characterized in that an electrical connection between adjacent helical windings (28) within a series (30) or column (32) via edge winding sections, or via a connection between exit points (36) for Windings (34) of a spiral winding (28) takes place, and in particular that within a row (30) or column (32), the electrical connections between edge winding sections and exit points (36) are alternating.

24. Induction heating device according to one of the preceding claims, characterized in that an electrical connection between adjacent rows (30) or columns (32) via a Randwicklungs- section and an output point (36) for turns (34) of adjacent spiral windings (28 ) he follows.

25. Induction heater according to one of the preceding claims, characterized in that the spiral windings (28) are formed as flat coils.

26. Induction heater according to one of the preceding claims, characterized in that the coil device (14) is designed to be self-supporting.

27. Induction heating device according to one of the preceding claims, characterized in that the coil device (14) on a support (12) is arranged.

28. induction heating device according to claim 27, characterized in that the carrier (12) is flexurally flexible and in particular is formed as a mesh and in particular is formed as a textile mesh.

29. Induction heating device according to claim 27 or 28, characterized in that the tube (16) via one or more holding threads (70) is held on the carrier (12).

30. A method of operating an induction heating device (10) according to any one of the preceding claims, wherein the heat transfer medium is conveyed through the tube (16).

31. The method according to claim 30, characterized in that on the heat transfer medium, a heating temperature of the induction heating device (10) is set.

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