DE2041234C - Device for inductive heating of objects such as transport pipes - Google Patents

Description

The present invention relates to a device for inductive heating of objects, such as transport tubes for transporting liquids and gases, consisting of at least one ferromagnetic tubular body through which an insulated wire is passed, which at least to one end connected to an AC power source, the other end to either end of the ferromagnetic tube or is returned directly to the AC power source.

Devices for heating pipes of this type are already known (see, for example USA patents 3,293,407 and 3,515,837 and the corresponding German patents 515 139 and 1 615 192).

One of these known devices is shown in Figs. La and I b. These figures show a ferromagnetic tubular body 1, which consists for example of steel. Because of this ferromagnetic Pipe body 1 leads an insulated wire 2. One end of the wire 2 is on the clamp S connected to an AC power source 3, while the other end to that of the AC power source 3 facing away from the side at 5 is attached to the ferromagnetic tubular body 1. The other end 4 of the ferromagnetic tubular body 1 is via a

ίο Wire to the other terminal on the AC power source 3 connected. In this way, alternating currents 6 and 6 'represented by arrows flow, each of which the alternating current 6 'flowing through the ferromagnetic tubular body 1

is only / on the inner surface of the tubular body 1 is concentrated.

The Fig.2a and 2b show the principle of the other known device. According to these figures, two ferromagnetic tubular bodies 7 and 7 'are made up

so steel provided. The two ends of these tubular bodies 7, 7 'are connected to one another via wires 8 and 8'. Furthermore, an insulated wire 9 is provided, which is guided through the ferremagnetic tubes 7, T. Both ends of the insulated wire 9 are connected to an AC power source 10. In this exemplary embodiment, induction currents 11 and 11 'are generated which flow through the ferromagnetic tubular bodies 7 and 7'. In this case too, the induced alternating current 11 flows only along the inner surfaces of the two tubular bodies 7, 7 '.

In the two known devices, as already mentioned, the alternating currents 6 'and 11' to flow, which is only concentrated on the inner surface of the ferromagnetic tube body are. As a result, there is essentially none on the outer surface of the ferromagnetic tubular body Tension recorded. Even if the outer surface of the ferromagnetic tube body through If a wire with low resistance is short-circuited, no current will be applied to the Outside of the ferromagnetic tube body. This ensures a very high level of operational reliability. Devices of this type are therefore suitable for the transport of liquids or gases serving transport pipes, road surfaces, floors or building walls od. The like. To heat or on a to maintain the specified temperature.

When using such devices it sometimes occurs that in some places the object to be heated, for example a transport pipe, a stronger heat development is required. For example, if a transport pipe is supported on pillars or brackets, the * heat can escape through these pillars or brackets. As a result, the temperature in these areas of the transport pipe are reduced more than in other areas. In the case of transport Viscous liquids can cause blockages in the area of these pillars or brackets to lead. In the case of the transport of condensable gases there is also the risk that an undesired Condensation takes place at these points. Accordingly, the present invention is dk The object is to create a device for the heating of objects such as transport pipes, which allows a strong "worm development" at given points.

According to the invention this is achieved in that the tubular body in the area of the desired increased heat development is cut through, and that the tubular body parts formed in the Area of the endpoints of the desired increased heating connected to one another by a conductor are.

Advantageous further developments result from the subclaims 2 to 7.

The present invention will now be explained in more detail on the basis of exemplary embodiments, reference being made to the drawing. Show it

F i g. 1 a, 1 b, 2 a and 2 b sectional views in the longitudinal and transverse directions of two known devices for heating pipes and

rig. 3a, 3b, 4a, 4b and 5a and 5b are side views - partly in section - and cross-sectional views of three embodiments of the device according to the invention for heating Pipelines.

F i g. 3 a and 3 b show a first exemplary embodiment of the invention with a transport tube 12 for transporting liquids or gases. An increase in the generation of heat is to be brought about within sections X and Y. According to the figures shown, the insulated wire 13 corresponds to the wire of FIGS. 1 a and 1 b or the wire 9 according to FIGS. 2a and 2b. Alternating current 14 flows through this wire 13; the currents 16 and 16 'correspond to the alternating current 6' according to FIG. 1 a and the alternating current 11 according to FIG. 2a.

In the context of the present invention, a tubular body is provided which is cut through at point 17, so that two tubular body parts 15, 15 'are present. The points 18 and 18 'on the outer surface of the ferromagnetic tubular body parts 15, 15' are connected to one another by a wire 19 at both ends of the section between X and Y. If the transport tube 12 intended for transporting liquids or gases is made of steel, its outer surface can serve as a conductor. In this case the two pipe body parts 15 and 15 'are welded on at points 18 and 18'. Due to such a subdivision, the current flowing through the pipe body parts 15 and 15 'now flows in the area of the section X and Y along both the inner and the outer surfaces of the pipe body 15, 15', a circuit according to FIG. 3 a is formed. The current 16 'thus flows along the inner surface of the tubular body part 15', reaches the cut end from the inner surface to the outer surface of the tubular body part 15 ', then flows at the connecting point 18' into the wire 19 and via the connecting point 18 to the tubular body part Current along the outer surface, passes from the outer surface to the inner surface at the end of the cut and finally continues to flow as inner surface current 16.

Thus, in areas A 'and Y , the same current flows both on the outer and on the inner surfaces of the tubular body parts 15, 15'. Since the generation of heat is brought about essentially by the current flowing along the ferromagnetic tubular body, it is understandable that an increase in heat is to be expected within the section X and Y.

In order to improve the transfer of the generated heat, an electrical insulating body with good thermal conductivity in the space between the ferromagnetic tube body parts 15 and 15 * and the transport tube 12 to be heated or the object to be heated. Such a substance is, for example, a thermally conductive binder, which mainly consists of Consists of graphite.

A further embodiment of the present invention is shown in FIGS. 4a and 4b. Reference number 12 'shows a steel transport pipe for transporting liquids or gases. The reference numerals 13, 14, 15, IS ″, 16 and 17 correspond to those of FIGS. 3a and 3b. A housing 20 made of ferromagnetic material, for example steel, is welded to the pipe body parts 15, 15 'and to the transport pipe 12'. This housing 20 is fastened on a column 21. According to FIG. 4a, the current 16 'flows along the inside of the pipe body 15', at the cut end to the outside and from there along the transport pipe 12 'and the inside of the housing 20. The current then flows along the outer surface of the pipe body part 15 to to the end of the cut and from there as an inner surface flow 16 along the inside of the tubular body part 15.

In this embodiment, no current occurs on the outer surfaces of the housing 20 and the transport tube 12 'if the components mentioned have a sufficient thickness. In this way, the safety during operation of the device is increased. The outer housing 20 also protects the part of the wire 13 which is exposed in the region of the gap 17. In the case of the FIGS. 4 a and 4 b, the heat to be generated between X and Y is approximately twice as great as the heat generated in the other areas of the tubular body.

Since the pipe body parts 15, 15 'are usually welded to the transport pipe 12' in order to improve the heat transfer, the temperature difference between the pipe bodies and the transport pipe 12 'is very small. However, since the areas of the tubular body parts 15, 15 'present between X and Y are only welded to their passages through the housing 20, it is possible that the temperatures of the tubular body in this area can rise to an unacceptable level. In order to avoid this, a thermally conductive binder 22, consisting essentially of graphite, can be filled into the housing, which has a poor electrical, but good thermal conductivity.

In FIGS. 5a and 5b, a third exemplary embodiment of the device according to the invention is shown, with which the amount of heat generated between the sections X and Y can be greatly increased. According to these figures, ferromagnetic rings, which can consist of steel, for example, are looped around the ferromagnetic tubular body within the section X and Y. The reference symbols 12 ', 13, 15, 15' and 17 correspond to those of FIG. 3 and the two pipe bodies 15 and 15 'are welded at 18 and 18' with their outer surfaces at the ends of the section X and Y on the transport pipe 12 '. The figures also show a holder 25 which is welded to the transport tube 12 '. This bracket 25 can - as at the beginning

mentioned - heat escape in an undesirable way. To compensate for this heat loss an eddy current is generated in the ferromagnetic rings 23; these eddy currents are caused by the Induced current, which on the one hand along the outer surface of the ferromagnetic tubular body parts 15 ', on the other hand along the existing between the points 18,18', through the transport tube 12 ' formed ladder flows. Because of the eddy currents heat is generated within the ferromagnetic rings 23. The thickness of this ferromagnetic Rings 23 is preferably more than twice the penetration depth of the eddy current. If the ferromagnetic Rings 23 are made of steel, and if the ferromagnetic tubular body parts 15, 15 'flowing current has the usual mains frequency, a thickness of 3 mm is usually sufficient. The number the ferromagnetic rings 23 can be selected depending on the desired heat generation. In Figs. 5a and 5b, the ferromagnetic Rings 23 shown with a circular cross-section, but rings with a right-angled, trapezoidal or other cross-section can be used. The ferromagnetic on these The heat generated by the rings 23 is preferably supplied to the transport tube 12 'by a binding agent 26. The binder 26 has a low electrical, but good thermal conductivity. The reason, why the binder 26 must have a low electrical conductivity is that a electrical short circuit between the transport tube 12 ', the ferromagnetic tube body parts 15, 15'

ίο and the ferromagnetic rings 23 prevented must become. Since the voltage difference between these components is within a range of a few volts, a thermally conductive binder consisting essentially of graphite can also be used sufficient results are used. In addition, a housing made of ferromagnetic Material according to Fig. 4a and 4b can be used, which the above-mentioned tubular body parts 15, 15 ' and the ferromagnetic rings 23 receives, where-

ao is increased by the operational safety, because no current flows off on the outside of the housing. the The part of the wire 13 that is exposed in the gap 17 can also be covered from the outside.

1 sheet of drawings

Claims (7)

Patent claims: 1. Device for inductive heating of objects, such as transport tubes for transporting liquids and gases, consisting of at least one ferromagnetic tubular body through which an insulated wire is passed, which is connected at least at one end to an alternating current source, the other end either to the The end of the ferromagnetic tube is connected or returned directly to the alternating current source, characterized in that the tube body is cut through in areas of the desired increased heat generation, and that the tubular body parts (15, 15 ') formed thereby in the area of the end points (X, Y) of the desired increased Heating by an electrical conductor (19, 12, 20) are connected to one another. 2. Apparatus according to claim 1, characterized in that the conductor is a wire (19). 3. Apparatus according to claim 1, characterized in that the conductor is part of the metallic transport tube (12) is. 4. Apparatus according to claim 1 or 3, characterized in that the conductor by a ferromagnetic housing (20) is formed. 5. Device according to one of the preceding claims, characterized in that the two tubular body halves (15, 15 ') are enclosed in the region (X, Y) of the desired increased heat generation by ferromagnetic rings (23). 6. Device according to one of the preceding claims, characterized in that the two tubular body halves (15,15 ') in the area (A', Y) of the desired increased heat generation are enclosed by a material of low electrical conductivity and good thermal conductivity, which with the to be heated object (12, 12 ') is in contact. 7. Apparatus according to claim 6, characterized in that the material is less electrical Conductivity and good thermal conductivity is a binder which is im consists essentially of graphite.