EP1856949A2

EP1856949A2 - Current supply for heaters

Info

Publication number: EP1856949A2
Application number: EP06723284A
Authority: EP
Inventors: Ilse Talle; Jörn SCHRÖER
Original assignee: Ewald Doerken AG
Current assignee: Ewald Doerken AG
Priority date: 2005-03-08
Filing date: 2006-03-08
Publication date: 2007-11-21
Also published as: WO2006094783A3; DE102005010470A1; WO2006094783A2; US20080283516A1; EA012089B1; EA200701890A1

Abstract

The invention relates to a current supply device for a surface resistance heater, a heating system and to a method for supplying a surface resistance heater with current. The resistance of the surface resistance heater is measured in a continuous manner in order to detect short-circuits. In the event of a short-circuit, the current is limited or cut-off. Said current supply device is, preferably, embodied as a skirting board or as a cover strip.

Description

Power supply for heaters

The invention preferably relates to an inverter as a power supply element with a technology in the protective extra-low voltage range for alternating or direct current from 0 volts to a corresponding uppermost protective extra-low voltage limit. In particular surface resistance heaters are to be heated with this technology. The present invention relates generally to a power supply device, preferably a power supply, for powering a surface resistance heater or a comparable heater.

In particular, the present invention relates to a power supply device according to the preamble of claim 1 or 6, a heating system according to the preamble of claim 30, a surface resistance heating and a method for supplying a surface resistance heating with electricity according to the preamble of claim 57.

From WO 2004/113798 Al a switching power supply for surface resistance heating is known. This switching power supply works as an inverter. Primary clocked inverters in this power range have capacitors in the primary circuit to smooth the rectified sine input voltage. These smoothing capacitors produce a phase shift between input voltage and input current. Since this phase shift leads to undesirable effects for the power companies, so-called Power Factor Controllers (PFC) are prescribed from a certain power class. In particular, these PFCs limit, control or regulate the reactive current or the reactive power. These PFCs require more or less volume depending on the power and are associated with significant costs. Another disadvantage of the known switching power supply is that in case of a short circuit in the connected resistance heating overload or overheating and in particular destruction can occur.

The present invention has for its object to provide a universally applicable and / or compact power supply device and a heating system, a sheet resistance heating and a method for supplying a Flächenwiderstandstandsheizung with electricity, in particular where by a Reduction in size is created the possibility to accommodate the electronics in a volume that allows to perform the power supply, for example, flush-mounted in a small flush-mounted housing, and / or the power supply and the surface heating, such as a heating wallpaper, in case of damage, for example by nails , Screws, dowels or other metallic objects are self-protected.

The above object is achieved by a power supply device according to claim 1 or 6, a heating system according to claim 30, a surface resistance heater according to claim 56 or a method according to claim 57. Advantageous developments are the subject of the dependent claims.

According to a first aspect of the invention measures the power supply device or preferably integrated into the power supply control to protect the system consisting of power supply device and connected heater - preferably continuously or permanently - the resistance of the heater, in particular foil, and thus detects any damage to the Heating (foil, heating wallpaper o. The like.). In particular, upon detection of an excessively high decrease in the electrical resistance (exceeding a rate of change and / or undershooting a minimum value) or a short circuit-for example due to damage to the surface heating-the power supply is interrupted or limited. For example, an undesirable overheating of the surface heating and any associated destruction can be avoided. Furthermore, an overloading of the power supply device due to excessive heating - in particular in the case of flush mounting - can thus be prevented in a simple manner.

According to a preferred embodiment, in particular a plurality of surface heating systems can be connected to the power supply device, in particular such that the resistances for the individual heaters can be detected independently of one another and / or the heaters can be switched off, regulated and / or limited in their current independently of one another.

According to a second aspect, which can also be implemented independently, of the present invention, the power supply device is designed as floor, foot, wiping, decoupling ken- or wall bar or rail or at least formed as a portion thereof or usable as such or integrated into or used. Particularly preferably, the power supply device is accordingly rail or profile-like, in particular elongated or rod-shaped. This allows a universal use of the proposed Stromversorgungsemrichtung and in particular a simple retrofitting of buildings, rooms or the like with the power supply device.

The power supply device is designed in particular as an inverter. The primary part of the inverter preferably has no smoothing condensers and / or no PFC. This is perfectly adequate for use as a power source for a surface heating element. The efficiency increases due to the loss of losses for PFC and smoothing or DC link capacitors.

Preferably, the secondary side as well as the primary side rectification, but no smoothing. In particular, a high-frequency filter is sufficient. Accordingly, secondary-side smoothing capacitors can be dispensed with, so that the size and cost can be minimized accordingly.

The inverter preferably has a regulator, which in particular is such that the rectified, but not smoothed output voltage or AC voltage does not correct.

The power supply device is preferably designed such that a connection surface is provided, in or on which at least one surface resistance heater, in particular a heating foil, or even more surface resistance heaters, in particular a plurality of heating foils, can be connected or can. The shading of the individual heaters is variable.

The proposed power supply device is preferably without

Foreign cooling or cooled with a fan, with one or more heat sinks or by a mechanism not described in detail. Alternatively or additionally, the housing of the power supply device for cooling the Power supply device formed and designed for this purpose, in particular at least partially metallic. For cooling and / or simple assembly, the power supply device may alternatively or additionally also be provided with a metallic rail, designed as such or attachable thereto.

In order to be able to use the power supply device as far as possible worldwide or universally, it preferably has an input voltage range of 90 to 400 VAC or volts. The frequency of the input voltage is variable in particular in the range of 50 to 60 Hz. Alternatively or additionally, any desired power of the power supply device or of the inverter which can be achieved with protective extra-low voltage can be realized or set.

The proposed surface resistance heating is particularly insensitive to damage, for example by nails, screws or the like, and even then generates no short circuit or is short-circuit-proof.

Further features, advantages, aspects and features of the present invention will become apparent from the claims and the following description of a preferred embodiment with reference to the drawing. It shows:

Fig. 1 is a schematic block diagram of a proposed power supply device; and

2 shows a schematic block diagram representation of a proposed heating system with the power supply device and with at least one associated surface heating.

1 shows a schematic block diagram of a proposed power supply device 1. The power supply device 1 is used, in particular, to supply at least one surface resistance heater 12, as indicated in FIG. 2, or the like with current.

The power supply device 1 has an input E for connection to the mains voltage. Preferably, the power supply device 1 is on AC voltage of 90 to 400 volts, in particular at least substantially 230 volts, connectable.

The power supply device 1 optionally has an input filter 2, in particular an EMC filter.

The power supply device 1 preferably has a rectifier 3, which rectifies the AC voltage, in particular in positive half-waves.

The power supply device 1 preferably has no DC smoothing on the primary side, in particular no smoothing capacitor or the like. The power supply device 1 further preferably has no PFC or the like. Alternatively, however, a DC smoothing and / or a PFC may be provided.

The DC voltage is supplied to a transformer or power transformer 5 of the power supply device 1 via switches Vl to V4 or a full bridge 4 or another suitable, in particular clockable or modulable switching device.

On the secondary side, the power transformer 5 is preferably followed by a secondary rectifier 6, which rectifies the alternating voltage output by the power transformer 5, ie in particular generates positive half-waves.

The current control device 1 preferably has no secondary side DC smoothing. However, this is possible in principle.

In the illustrated example, the current control device 1 optionally has an output filter 7 on the secondary side, which filters out high-frequency interferences or harmonics, preferably, as is the case with the optional input filter 2.

The power supply device 1 has a terminal A for the output voltage, in particular a protective extra-low voltage. At the port A is at least one surface resistance heater 12 connected or connected.

The power supply device 1 preferably also has a control and / or regulating device, in particular a controller 9. In the illustrated embodiment, the controller 9 is preferably connected via an optional optocoupler 8 to the output A of the current control device 1 - in particular for detecting the output voltage and / or the output current - connected. Next, the controller 9 is preferably connected to the primary side of the power transformer 5 - in particular for current detection.

The control or regulating device, in particular the controller 9, controls in the illustrated example, the switches Vl to V4 or the full bridge 4 or other switching device, in particular for input or primary side timing of the current control device 1 and the power transformer 5 voltage supplied, preferably by pulse width modulation. The timing or modulation takes place in particular with a frequency of 3 to 150 kHz. Preferably, the control is carried out such that alternately the switches Vl and V4 are closed and the switches V2 and V3 are opened and vice versa.

The current control device 1 or its control or regulation is preferably designed such that the output voltage is controllable or controllable, in particular from 0 volts to a low-voltage upper limit of 30 or 36 or 60/66 volts (RMS voltage or peak voltage), particularly preferably continuously.

The regulation or its time constant is preferably carried out in such a way, in particular sufficiently slowly, that the fluctuations of the output voltage are preferably not compensated in the absence of secondary-side DC smoothing. However, in principle, a regulation is possible, which corrects these voltage fluctuations and in particular leads to a smoothing.

The proposed power supply device 1 preferably converts the input-side DC voltage into an AC voltage. The power supply device 1 is thus designed in particular as an inverter or operates as such. However, in principle, other realizations are possible, for example, in principle, the AC line voltage can be clocked without rectification in a suitable manner or modulated or modified in any other way.

In the illustrated example, preferably a temperature sensor 10, such as an NTC, can be connected to the power supply device 1, preferably wirelessly or not wired, in particular via infrared or radio. Alternatively, however, a connection via a cable or the like is possible.

The temperature sensor 10 is used in particular for detecting the room temperature. It is preferably located either in the vicinity or relatively far from the power supply device 1 at a suitable location.

The temperature sensor 10 in particular provides an actual value for a preferred control or regulation of the room temperature.

The power control supply device 1 is preferably associated with a control device, such as a potentiometer 11 or the like, in particular for setting the heating power and / or for switching on and off. In the illustrated example, the control device is preferably wirelessly or not wired-connected - in particular via infrared or radio - to the power supply device 1. However, the control device may also be connected to the power supply device 1 via cables or the like, or may be arranged on the power supply device 1 or integrated into it.

The control device or the potentiometer 11 serve, in particular, for specifying a desired room temperature, that is to say a desired value, for the preferred temperature control, in particular the controller 9.

The power supply device 1 is preferably designed such that the electrical resistance of at least one connected surface resistance heater 12 can be measured or detected. In the illustrated example, this is preferably done on the one hand by measuring or detecting the output voltage and on the other hand by detecting the primary-side and / or output-side current.

The resistor is preferably monitored continuously or permanently by the power supply device 1 or the controller 9 or another control or regulating device of the power supply device 1.

Upon detection of an excessive drop in the electrical resistance (exceeding a rate of change and / or falling below a minimum value) or upon detection of a short circuit of the surface resistance heater 12, the current or the power supply for the surface resistance heater 12 is preferably switched off or at least limited. The limitation may be, for example, to a predefinable value or to a previous value (if appropriate averaged) before detection of the excessive sharp drop in the electrical resistance or short circuit. For example, in case of damage to the surface resistance heater 12 by a metallic object or otherwise possible overheating and possibly further destruction of the surface resistance heater 12 and / or a possible overheating and possibly destruction of the power supply device 1 and / or other objects are prevented.

As an alternative or in addition to the electrical resistance, a value proportional thereto or otherwise correlated, in particular the electrical current, can be monitored in a corresponding manner.

According to a first embodiment variant, only a single surface resistance heater 12 can be connected to the power supply device 1. According to a second embodiment, a plurality of surface resistance heaters 12 can be connected to the power supply device 1, in particular in parallel and / or in series.

In the case of the second embodiment, the surface resistance heaters 12 or their heating elements are preferably individually or groupwise independently supplied with power and / or their electrical resistances or their currents measurable or detectable, in particular so that when excessively star core resistance drop or short circuit, the surface resistance heaters 12 and their heating elements individually or in groups can be switched off or limited in the stream.

According to a further embodiment variant, the power supply device 1 is preferably designed such that the output current is always limited to a maximum value relative or in addition to the already described resistance monitoring and power cut-off in the event of excessive resistance drop or short circuit.

The individual components or components of the power supply device 1 are preferably accommodated in a common housing. Alternatively or additionally, the components or components are cast in particular in plastic.

The power supply device 1 is preferably waterproof. This is very easy and inexpensive to implement in particular by pouring into plastic.

2 shows a schematic representation of a proposed heating system consisting of a power supply device 1 and at least one surface resistance heater 12 and a proposed surface resistance heater 12. In the illustrated example, two surface resistance heaters 12 are connected to the same power supply device 1.

The connection of the surface resistance heater 12 can be carried out, for example, in that electrodes 13 of the surface resistance heaters 12 are guided directly to a corresponding contact surface on and / or in the housing of the power supply device 1. Alternatively, a connection can also be made via electrical cables, not shown, or the like. The cables are then, for example pluggable connected to the power supply device 1 or firmly connected to this. In particular, in the latter case, the cables preferably have at their other ends suitable connection devices, contact surfaces or the like for electrical connection to the respective surface resistance heater 12 or electrode 13. The surface resistance heaters 12 or their heating elements connected to the power supply device 1 or their heating elements are preferably made of conductive carbon, carbon fibers, a coal-carbon mixture with non-conductive materials, a carbon fiber fleece, a carbon fiber glass fiber fleece mixture, carbon fiber industry, A carbon fiber-glass fiber-fabric blend, graphite-coated with a conductive binder, supported on or formed from a nanotube carbon fiber web, or a nanotube carbon fiber blend with non-conductive materials or blends thereof. In particular, an electrically conductive heating layer consists of this material or these materials. The electrodes 13, which are designed in particular as parallel strips, are then preferably additionally provided. Further, another carrier layer, cover layer, insulation or the like may be provided.

The sheet resistance heater 12 heats in particular over the entire surface and is preferably flexible, in particular foil-like, fleece-like or fabric-like. This started a simple installation and a universal use.

However, in principle, other surface resistance heaters or other heaters may be connected to the proposed power supply device 1 instead of the surface resistance heaters 12 described above.

The surface resistance heaters 12 may, for example, be laid or installed on a floor 14 and / or on a wall 15, as shown by way of example in FIG. 2.

The power supply device 1 can be designed or provided, for example, as a flush-mounted box or for other installation. Preferably, however, the power supply device 1 is rail, profile or rod-shaped or elongated.

In the illustrated embodiment, the power supply device 1 is particularly preferred as floor, foot, wiping, ceiling or wall strip 16 or at least formed as a section thereof or in such a bar 16 can be installed. This allows a very universal use and a simple surface mounting. The preferred embodiment of the power supply device 1 as floor, foot, wiping, ceiling or wall strip 16 or at least as a section thereof allows a particularly simple connection of the associated surface resistance heater 12, especially if this extends to below the power supply device 1 or bar 16 , Required connections or the like are then in fact covered by power supply device 1 or strip 16.

If necessary, the power supply direction 1 can be connected to a preferably metallic rail and / or forms at least a portion of a preferably metallic rail. This allows for easy installation and in particular the use as previously mentioned bar 16th

Particularly preferably, the power supply device 1 has an at least partially metallic housing for cooling. Alternatively or additionally, cooling can take place via the abovementioned metallic rail.

Additionally or alternatively, a plurality of power supply devices 1 can be connected to each other, in particular pluggable, particularly preferably for mechanical and / or electrical connection. In particular, an input side and / or output side parallel connection of the power supply device 1 in a very simple manner is possible. Furthermore, a modular structure is made possible.

Claims

claims:

1. power supply device, (1) in particular inverter, as a power supply or Stromzuföhrungselement, preferably with a technology in Schutzkleinspannungsbereich for AC and / or DC from 0 volts to the corresponding uppermost protective extra-low voltage limit for at least one surface resistance heater (12), characterized in that the Power supply device (1) for measuring or detecting the resistance of the surface resistance heater (12) is formed.

2. Power supply device according to claim 1, characterized in that the power supply device (1) is designed for permanent resistance measurement of the connected surface resistance heater (s) (12) and preferably for detecting short-circuits and / or self-protecting is formed before overtemperatures.

3. Power supply device according to claim 1 or 2, characterized in that in particular when the resistance or short circuit of the sheet resistance heater (12) - especially in the affected surface resistance heating (12) - the current is limited or reduced or the power supply is turned off.

4. Power supply device (1) according to any one of the preceding claims, characterized in that a plurality of surface resistance heaters (12) to the power supply device (1) can be connected, in particular so that the power supply to the individual surface resistance heaters (12) is independently limited or can be switched off.

5. Power supply device (1) according to one of the preceding claims, characterized in that the power supply device (1) for flush mounting, in particular as a flush-mounted box is formed.

6. power supply device (1), in particular inverter, for at least one surface resistance heater (12), in particular according to one of the preceding claims, characterized in that the power supply device (1) as a floor, foot, wiping, Deckenoder wall strip (16) or at least designed as a section thereof or can be installed therein.

7. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) is preferably encapsulated waterproof.

8. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) or the secondary part of the power supply device (1) has a control which - in particular due to a lack of secondary side Gleichstromglättung occurring - corrects voltage fluctuations or not corrects.

9. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) does not have to be cooled or is cooled by a fan, a device without external cooling or by water.

10. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) has an at least partially metallic housing for cooling.

11. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) rail, profile or rod-shaped or elongated.

12. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) with a pre is preferably connectable to metallic rail and / or forms at least a portion of a preferably metallic rail.

13. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) is formed in particular pluggable, mechanical and / or electrical connection with another, in particular the same power supply device (1), preferably to the input side and / or output side parallel connection.

14. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) is formed or constructed from a plurality of individual elements or components.

15. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) or their

Components (2 to 9) is cast in particular in plastic or are.

16. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) forms a Bauein- unit.

17. Power supply device according to one of the preceding claims, characterized in that the rms value of the input voltage of 90 to 400 volts AC voltage can vary.

18. Power supply device according to one of the preceding claims, characterized in that the frequency of the input voltage can vary in particular in a range of 50 to 60 Hz.

19. Power supply device according to one of the preceding claims, characterized in that the amplitude of the output voltage or power supply in a range of 0 volts to the maximum allowable voltage, in particular of 30 or 36 volts or 60/66 volts, is adjustable.

20. Power supply device according to one of the preceding claims, characterized in that the output to the surface resistance heater (12) power limited, controllable or regulated.

21. Power supply device according to one of the preceding claims, characterized in that a desired room temperature as a setpoint - in particular by means of a potentiometer or other control device (11) - can be predetermined, in particular wherein the actual room temperature as the actual value by a preferably directly to the power supply closable temperature sensor (10), such as an NTC, is measurable.

22. Power supply device according to claim 21, characterized in that the potentiometer or another control device (11) and / or the temperature sensor (10) in the vicinity of the power supply device (1), in particular at a distance of about or up to 20 cm , or is arranged spatially further away or are.

23. Power supply device according to claim 21 or 22, characterized in that the desired value and / or actual value wirelessly or not Leistungsgebun- the - preferably via infrared or wireless - is transferable or are.

24. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) operates on the primary side and / or secondary side without Gleichstromglättung.

25. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) has a primary switching regulator (4, 9) which operates preferably with or without intermediate circuit capacitor.

26. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) has no or a PFC.

27. Power supply device according to one of the preceding claims, characterized in that the power supply device (1) for detecting the own temperature or of at least one component (2 to 9) of the power supply device (1) or the temperature in a housing of the power supply device ( 1), in particular wherein the power supply can be throttled or interrupted upon detection of an excessive temperature.

28. Power supply device according to one of the preceding claims, characterized in that only one surface resistance heater (12) or only a surface resistance heating element can be connected.

29. Power supply device according to one of claims 1 to 27, characterized in that a plurality of surface resistance heaters (12) or surface resistance heating elements - in particular by a suitable connector - in series, in parallel or in a mixture can be connected or connected.

30. Heating system with a power supply device (1) and a sheet resistance heater (12), characterized in that the power supply device (1) according to one of the preceding claims and / or is designed as an inverter and / or that the surface resistance heater (12) or its heating element in particular of conductive carbon, carbon fibers, a carbon fiber mixture with non-conductive materials, a carbon fiber nonwoven fabric, a carbon fiber-glass fiber nonwoven blend, carbon fiber fabric, carbon fiber-glass fiber fabric blend, provided on graphite with a conductive binder Carrier is made or made of a nanotube carbon fiber web or of a nanotube carbon fiber mixture with non-conductive materials.

31. Heating system according to claim 30, characterized in that only one surface resistance heater (12) or only one surface resistance heating element is connected to the power supply device (1).

32. Heating system according to claim 30, characterized in that a plurality of surface resistance heaters (12) or surface resistance heating elements are connected to the power supply device (1).

33. Heating system according to claim 32, characterized in that the surface resistance heaters (12) or surface resistance heating elements individually or in groups independently supplied with power and / or - especially in case of strong resistance drop or short - switched off or in the current limited.

34. Heating system (1) according to any one of claims 30 to 33, characterized in that the power supply device (1) for flush mounting, in particular as a flush-mounted box is formed.

35. Heating system according to one of claims 30 to 34, characterized in that the power supply device (1) is preferably encapsulated waterproof.

36. Heating system according to one of claims 30 to 35, characterized in that the power supply device (1) or the secondary part of the power supply device (1) has a control that - especially due to a lack of secondary side DC smoothing occurring - compensates or not corrects ,

37. Heating system according to one of claims 30 to 36, characterized in that the power supply device (1) does not have to be cooled or is cooled by a fan, a device without external cooling or by water.

38. Heating system according to one of claims 30 to 37, characterized in that the power supply device (1) is an at least partially metallic

Has housing for cooling.

39. Heating system according to one of claims 30 to 38, characterized in that the power supply device (1) rail, profile or rod-shaped or elongated.

40. Heating system according to one of claims 30 to 39, characterized in that the power supply device (1) is connectable to a preferably metallic rail and / or forms at least a portion of a preferably metallic rail.

41. Heating system according to one of claims 30 to 40, characterized in that the power supply device (1) for in particular pluggable, mechanical and / or electrical connection with another, in particular the same power supply device (1) is formed, preferably to the input side and / or output side parallel connection.

42. Heating system according to one of claims 30 to 41, characterized in that the power supply device (1) is formed or constructed of a plurality of individual elements or components.

43. Heating system according to one of claims 30 to 42, characterized in that the power supply device (1) or its components (2 to 9) is cast in particular in plastic or are.

44. Heating system according to one of claims 30 to 43, characterized in that the power supply device (1) forms a structural unit.

45. Heating system according to one of claims 30 to 44, characterized in that the rms value of the input voltage of 90 to 400 volts AC voltage can vary.

46. Heating system according to one of claims 30 to 45, characterized in that the frequency of the input voltage can vary in particular in a range of 50 to 60 Hz.

47. Heating system according to one of claims 30 to 46, characterized in that the amplitude of the output voltage or power supply in a range of 0 volts to the maximum allowable voltage, in particular of 30 or 36 volts or 60/66 volts, is adjustable.

48. Heating system according to one of claims 30 to 47, characterized in that the output to the surface resistance heater (12) power is limited, controllable or regulated.

49. Heating system according to one of claims 30 to 48, characterized in that a desired room temperature as a setpoint - in particular by means of a potentiometer or other control device (11) - can be specified, in particular wherein the actual room temperature as an actual value by a preferably directly to the power supply device connectable temperature sensor (10), such as an NTC, is measurable.

50. Heating system according to claim 49, characterized in that the potentiometer or other control device (11) and / or the temperature sensor (10) in the vicinity of the power supply device (1), in particular at a distance of about or up to 20 cm, or is arranged spatially further away or are.

51. Heating system according to claim 49 or 50, characterized in that the desired value and / or actual value wirelessly or not power-bound - preferably via infrared or radio - is or can be transmitted.

52. Heating system according to one of claims 30 to 51, characterized in that the power supply device (1) operates on the primary side and / or secondary side without Gleichstromglättung.

53. Heating system according to one of claims 30 to 52, characterized in that the power supply device (1) has a primary switching regulator (4, 9), which preferably operates without or with a DC link capacitor.

54. Heating system according to one of claims 30 to 53, characterized in that the power supply device (1) has no or a PFC.

55. Heating system according to one of claims 30 to 54, characterized in that the power supply device (1) for detecting the own temperature or of at least one component (2 to 9) of the power supply device (1) or the temperature in a housing of the power supply device (1), in particular wherein the power supply can be throttled or interrupted upon detection of an excessive temperature.

56. surface resistance heating (12), wherein the surface resistance heating (12) or its heating element of conductive carbon, carbon fibers, a carbon fiber mixture with non-conductive materials, a carbon fiber fleece, a carbon fiber-glass fiber fleece blend, carbon fiber fabric Carbon fiber-glass fiber-fabric mixture, made of graphite provided with a conductive binder applied to a carrier or made of a nanotube carbon fiber web or of a nanotube carbon fiber mixture with non-conductive materials or is prepared.

57. A method for supplying a surface resistance heating (12) with power, in particular where the equal-weighted mains voltage is transformed by means of a preferably primary-side clocked inverter and a transformer or transformer (5) and output as preferably rectified low voltage to the surface resistance heater (12) and / or a low voltage which is adjustable or variable, preferably from 0 V to the protective extra-low voltage limit, is output to the surface resistance heater (12), characterized in that the resistance of the surface resistance heater (12) is continuously measured and that upon detecting an excessively high resistance drop or a short circuit the current limited or switched off.

58. The method according to claim 57, characterized in that a power supply device (1) and / or a heating system according to one of the preceding claims is used.