DE4432979A1 - Heat generator - Google Patents

Abstract

A single appliance should at the same time heat and move or transport a medium. The invention should allow any medium to be directly and quickly heated. For that purpose, the secondary circuit (2) is preferably made of a tube-shaped composite metal sheet. The inner tube (3) of the composite metal sheet is made of a ferromagnetic material and the outer tube (4), which lies nearer to the primary circuit (1), is made of a non-ferromagnetic but good electroconducting material. Several variations of the secondary circuit (2) are disclosed. The heat generator can be applied in all fields where a medium must be directly heated.

Description

Technical field

The invention relates to an electrical machine with which Contrary to conventional designs with the help of induction Heat is to be generated in the secondary part.

State of the art

Rotating electrical machines of conventional design are like this constructed that the heat generated by the operation is low is kept and also the heat still generated to a maximum is dissipated.

The use of induction to heat a wide variety Fabrics are already known. So z. B. in the patent DE 31 29 715 entitled "Electromagnetic Liquid heating "an induction coil with a magnetic closed full iron coil core for heating a Liquid used.

Critique of the state of the art

The heat sources have smaller or narrowly limited ones heat-emitting surfaces. A continuous regulation is only possible with great effort. To transfer heat Heat exchanger necessary. The warming and the simultaneous Movement or transportation of a medium with a single one Device is with the currently known devices and facilities not possible.

problem

The invention specified in claim 1 is the problem based on the conventional electric generator, who converts mechanical energy into electrical energy, one To create heat generators that use electrical energy Converts thermal energy and, if desired, part of it Energy also converts into mechanical energy. Farther is to heat a medium by means of a single device can be achieved simultaneously with the movement of the medium or allows transportation. Furthermore, a direct and  rapid heating of any substances by the invention be made possible.

Achievable advantages

The advantages that can be achieved with the invention are in particular in the fact that rapid heating of the materials, even more massive Body, direct, targeted and regulated at the slightest Losses is possible. There are surfaces of almost any size for maximum and quick heat release and used. Physical and chemical processes can be cheap to be influenced. With the combination of warming and Mixing or heating and transportation by a single device there is therefore no need for additional equipment. So it can substantial cost savings can be achieved. Further increased the security of the system because of the electrical Power supply to components in the working medium is missing because the Energy is supplied via a magnetic field.

Further embodiment of the invention

Advantageous embodiments of the invention in detail constructive details and as a combined device for heating and for moving or transporting liquid or gaseous substances are specified in claims 2 to 10. Another variant of the heat generator with one fixed secondary circuit and the most varied constructive changes to adapt to special Applications are described in claims 11 to 21. in the Claim 22 states that in addition to the inner pole arrangement the outer pole arrangement is conceivable.

Description of several embodiments

The embodiments of the invention are in the drawing are shown and are described in more detail below. Show it

Fig. 1 shows a schematic representation of the heat generator with a distributed winding in the primary circuit and the secondary circuit with a composite sheet in tubular form,

Fig. 2 schematic representation of the heat generator with a secondary circuit, wherein the non-ferromagnetic outer tube is again divided into an inner and an outer tube, and both tubes are held by spacer elements in a defined distance to each other,

Fig. 3 schematic representation of the heat generator with a secondary circuit, wherein the ferromagnetic inner tube and the non-ferromagnetic outer tube are held by spacers at a defined distance to each other,

Fig. 4 schematic sectional view of the heat generator in the longitudinal direction and multi-partition secondary circuit,

Fig. 5 schematic representation of the heat generator with a secondary circuit in the form of a truncated cone and attached thereto wings and agitators,

Fig. 6 schematic representation of the heat generator with a secondary circuit in the form of a truncated cone with a closed cover and base, and a worm arranged thereon and a fixed thermal tube,

Fig. 7 schematic representation of the heat generator with a multi-divided thermal tube,

Fig. 8 shows a schematic representation of the inner pole design.

The basic structure of the heat generator according to the invention differs from the conventional electrical generator by the following changes. The primary circuit 1 , regardless of whether with concentrated or distributed winding, is always fed by an AC or three-phase circuit. The slot pitch with a distributed winding preferably has an extremely large slot pitch to increase the ratio of main field to stray field. Large groove widths and open grooves are preferably used. The operating temperature of the primary circuit 1 corresponds to that of conventional electrical machines. The primary circuit 1 further comprises a shell construction 10 . The secondary circuit 2 is made in the basic version from a composite sheet in the form of a tube. The inner tube 3 of the composite sheet consists of a ferromagnetic material of small thickness. The outer tube 4 of the composite sheet, which is closer to the primary circuit 1 , consists of a non-ferromagnetic material with good electrical conductivity, preferably of copper sheet. The air gap 5 between the primary circuit 1 and the secondary circuit 2 is advantageously larger than in conventional electrical machines.

By the device connected to the primary circuit 1 alternating or rotating field, a voltage is induced in the secondary circuit 2 which drives the current in the secondary circuit 2 and produces the desired heat in this via the resistor of the secondary circuit. 2 The process temperature that arises in the secondary circuit 2 can be adjusted by changing the induction and / or frequency and / or the air gap 5 . By designing the secondary circuit 2 , the cos can be influenced favorably. The small thickness of the composite sheets of the secondary circuit 2 and the resulting low mass minimizes the heat capacity. The structural design in several nested tubes significantly increases the surface.

The secondary circuit 2 can be modified for additional functions, for example the shape of a cylinder or another non-cylindrical shape with wings 9 , whirlers 9 or screws 9 .

A favorable design variant results from the following structure. The secondary circuit 2 consists of a rotatably mounted inner composite sheet in tubular form, the inner tube 3 having ferromagnetic properties and the outer tube 4 , which is closer to the primary circuit 1 , having non-ferromagnetic but good electrical conductivity properties and a fixed outer thermal tube 8 non-ferromagnetic but electrically good conductive material. The thermal tube 8 can again be divided into a plurality of tubes inserted into one another, it being possible for one or more of these tubes to be movable in the circumferential direction.

In a further variant, the inner composite sheet in tubular form is replaced by a composite sheet tube 7 with the embodiment of a hollow truncated cone. Swirlers 9 and / or blades 9 and / or a worm 9 can be arranged on the inner and / or outer circumference. The truncated cone can also be closed with a top and base surface 12 .

Furthermore, the secondary circuit 2 can be arranged in a fixed manner. Here, too, the secondary circuit 2 consists of a composite sheet in tubular form, the outer tube 4 of the composite sheet being able to be divided again into an inner and an outer tube. These two tubes are then expediently held at a defined distance by spacer elements 6 . Or the composite sheet is separated again into an inner tube 3 and an outer tube 4 . Both tubes are again held at a defined distance by spacer elements 6 .

There is also a possibility that the inner Composite sheet by a purely ferromagnetic or a pure non-ferromagnetic but electrically good conductive material is replaced.

The secondary circuit 2 can surround a thermally poorly conductive body 11 consisting of a low heat capacity.

The heat generator can also have rotatably mounted non-ferromagnetic but electrically highly conductive parts of the secondary circuit 2 with segment-shaped conductor surfaces which are not electrically connected to one another. Furthermore, the secondary circuit 2 can have openings. In the case of non-aggressive media, the sleeve construction 10 can be omitted. The secondary circuit 2 can be partially or completely in the form of coils or meandering with an air gap 5 between the individual layers, with an electrical connection partially or completely between the tube segments if a separation into segments is selected.

In addition to the round design of the primary circuit 1 and the secondary circuit 2 , special applications will also require any other shapes, the air gap 5 not to run constantly, the secondary circuit 2 to consist of individual rings and / or the secondary circuit 2 and / or the primary circuit 1 to divide several times. But it is also conceivable for the primary circuit 1 to be interchanged with the secondary circuit 2 , that is, instead of the inner pole version, the outer pole version is selected.

Claims (22)

1. Electrical machine in the form of a heat generator with a primary circuit as the excitation circuit, which has conventionally known windings with a concentrated or distributed design and a secondary circuit for generating heat, characterized by the following features:

• - The primary circuit ( 1 ), preferably with large groove widths and open grooves, fed by an AC or three-phase circuit, is designed so that it is at an operating temperature of conventional electrical machines and comprises a shell construction ( 10 ) made of non-ferromagnetic material,
• - The secondary circuit ( 2 ) consists of a fixed or mounted composite sheet in tubular form, the inner tube ( 3 ) of the composite sheet consists of a ferromagnetic material and the outer tube ( 4 ), which is closer to the primary circuit ( 1 ), from a non-ferromagnetic but there is electrically good conductive material,
• - The air gap ( 5 ) between the primary circuit ( 1 ) and secondary circuit ( 2 ) is advantageously chosen larger than in conventional electrical machines.

2. Heat generator according to claim 1, characterized in that the secondary circuit ( 2 ) consists only of a ferromagnetic or only of a non-ferromagnetic but electrically good conductive material. 3. Heat generator according to claim 1 and 2, characterized in that the secondary circuit ( 2 ) surrounds a thermally poorly conductive, consisting of low heat capacity body ( 11 ). 4. Heat generator according to claim 1 to 3, characterized in that the rotatably mounted parts of the secondary circuit ( 2 ) made of non-ferromagnetic but electrically conductive material with wings ( 9 ), whirlers ( 9 ) or screws ( 9 ) on the outer circumference expediently from the same Material are provided. 5. Heat generator according to claim 1 to 4, characterized in that the rotatably mounted parts of the secondary circuit ( 2 ) with wings ( 9 ), whirlers ( 9 ) or screws ( 9 ) on the inner circumference of any material, the rotatably mounted parts made of non-ferromagnetic but electrically good conductive material but are preferably made of the same material. 6. Heat generator according to claim 1 to 5, characterized in that the secondary circuit ( 2 ) consists of a rotatably mounted inner composite sheet in tubular form, wherein the inner tube ( 3 ) has ferromagnetic properties and the outer tube ( 4 ) which to the primary circuit ( 1 ) is closer, has non-ferromagnetic but good electrical conductivity and a fixed outer thermal tube ( 8 ) with a cylindrical or other shape is made of non-ferromagnetic but good electrical material. 7. Heat generator according to claim 6, characterized in that the outer thermal tube ( 8 ) consists of several nested individual tubes which are spaced apart and / or partially movable in the circumferential direction and / or provided with openings. 8. Heat generator according to claim 1 to 7, characterized in that an inner composite sheet metal tube ( 7 ) has the shape of a hollow truncated cone or other non-cylindrical shapes and thus the air gap ( 5 ) of the heat generator is not constant. 9. Heat generator according to claim 8, characterized in that the inner composite sheet tube ( 7 ) has a closed top and bottom surface ( 12 ). 10. Heat generator according to claim 1 to 4, 6 and 7, characterized in that the secondary circuit ( 2 ) in addition to the outer thermal tube ( 8 ) has a closed top and bottom surface ( 12 ). 11. Heat generator according to claim 1 to 4 and 10, characterized in that the fixed secondary circuit ( 2 ) consists of a composite sheet in a tubular shape, in which the outer tube ( 4 ) is again divided into one or more tubes and these by spacers ( 6 ) are held at a defined distance from one another, individual tubes from the outer tube ( 4 ) being movable in the circumferential direction. 12. Heat generator according to claim 1 to 4, 10 and 11, characterized in that the fixed secondary circuit ( 2 ) in an independent inner tube ( 3 ) made of ferromagnetic material and one or more independent outer tubes ( 4 ) made of non-ferrous magnetic but electrically good are divided conductive material and these outer tubes ( 4 ) by spacers ( 6 ) are kept at a defined distance from each other. 13. Heat generator according to claim 11 and 12, characterized in that the inner tube ( 3 ) has a closed top and bottom surface ( 12 ). 14. Heat generator according to claim 1 to 13, characterized in that rotatably mounted non-ferromagnetic but electrically highly conductive parts of the secondary circuit ( 2 ) consist of segment-shaped conductor surfaces which are not electrically connected to each other. 15. Heat generator according to claim 1 to 14, characterized in that the secondary circuit ( 2 ) has openings. 16. Heat generator according to claim 1 to 15, characterized in that the secondary circuit ( 2 ) partially or completely consists of a grid and / or a gauze and / or a braid. 17. Heat generator according to claim 1 to 16, characterized in that the primary circuit ( 1 ) and / or the secondary circuit ( 2 ) has an elliptical, angular, wavy or any other shape. 18. Heat generator according to claim 1 to 17, characterized in that the secondary circuit ( 2 ) parallel to the inner tube ( 3 ) has further ferromagnetic tubes. 19. Heat generator according to claim 1 to 18, characterized in that the secondary circuit ( 2 ) is partially or completely preferably in the form of a coil or meandering with an air gap ( 5 ) between the individual layers, wherein an electrical connection partially or completely between the Pipe segments exist if a separation into segments is selected. 20. Heat generator according to claim 1 to 19, characterized in that the primary circuit ( 1 ) and / or the secondary circuit ( 2 ) are divided several times. 21. Heat generator according to claim 1 to 20, characterized in that the primary circuit ( 1 ) is formed without an envelope structure ( 10 ). 22. Heat generator according to claim 1 to 21, characterized in that the primary circuit ( 1 ) with the secondary circuit ( 2 ) is geometrically interchanged, ie that the outer pole arrangement is selected instead of the inner pole arrangement.