DE10361523A1 - A heating system has carbon fibre conductors within a tube having insulating material and heat conducting material which avoids electrical hazards due to a breaking of the conductor - Google Patents

Abstract

In one example of an embedded system in a house wall (17) the carbon fibre conductor (10) is surrounded by electrical insulation (14) inside a tube (11) containing a heat conducting medium (15) so that the conductor is isolated in the event of a breakage.

Description

The The invention relates to a heating device according to the preamble of the claim 1.

A Such heater has been known recently.

The Invention is to provide such a known heater in the With regard to safety aspects.

This is with a heating device, as in the claims 1 and 4 is reached.

To is in a heater with a for connection to a electric power source provided filament, wherein the filament consists of a carbon or a carbon compound or designed as carbon fiber is and the filament a heat radiator is assigned, according to claim 1 provided that the heat radiator off an electrically conductive Material manufactured and used as a neutral or return conductor in case of possible damage of the filament is provided.

alternative is at one in a heater with one for connection to a electric power source provided filament, wherein the filament consists of a carbon or a carbon compound or designed as carbon fiber is and the filament a heat radiator is assigned, according to claim 4 provided that the filament in one with a thermally conductive medium filled Tube, tube or sheath is arranged and that the medium as electrically conductive medium accomplished and to function as a neutral or return conductor in case of possible damage of the filament is provided.

Of the Advantage of the invention is that in case of damage to the Heating device, e.g. through one on the filament while turning in the wall nail, a personal danger is excluded, because either directly over the damaged Filament at the point of damage in contact with the as return conductor functioning heat radiator or the same as the return conductor functioning medium, is standing, the current can flow back to earth. If no such direct contact between filament and heat radiator or Medium exists, usually results at least one indirect contact, namely about the chosen nail or similar. Also in this case, the return of the current to the earth ensured.

The dependent claims are on preferred embodiments directed to the present invention.

Of the Advantage of the invention and its embodiments is thus in particular in that essential claims the building biology met become. Since no electromagnetic field is built up, results a low power consumption and thus a high efficiency the heater in proportion to the current used. After no electromagnetic field is built, arises also no so-called "electrosmog". In addition, the Heating device with comparatively low operating temperatures of about 100 ° C be operated so that no combustion of dust or other takes place in the room or ambient air particles. After all takes place due to the fact that the heat almost exclusively in Form of heat radiation is discharged, no convection takes place, so that e.g. no dust whirled up becomes. Furthermore, the heater is maintenance free.

The Heater is suitable for use as a wall, floor and ceiling heating. In case of use as wall heating is also an execution in the form of a wall-mounted underfloor heating possible, because the used Plasters are usually good heat conductor are and therefore the surface the wall as a heat radiator can act.

The Heater is also suitable for outdoor use, e.g. for frost protection for gutters, Pipes, sidewalks, bridges, etc., for heating of outdoor machines such as e.g. Construction machinery, or for heating means of transport, such. containers Truck semi-trailers, railway wagons and the like. Finally, the Heating device can also be incorporated into tissue, tarpaulins or the like, as they are e.g. as curtains, at tents, market stalls, Covers (e.g., covers of food to avoid Frost) and the like are usable. Such fabrics or tarpaulins are e.g. also for temporary and / or local heating in stables or the like useful. In this way, e.g. at valuable Sport horses a possibility to heat the respective horse box or the trailer quickly be set up.

At the Drywall leaves the invention is particularly favorable by using the heater in known drywall elements, ie in particular expansion panels, such as Plasterboard, chipboard and the like is introduced. The heater can be special also be used advantageously for building drying. This results mainly due to the fact that the heat is essentially in shape of heat radiation is delivered.

The heat release in the form of heat radiation and the concomitant lack of Kon vection also makes the heater interesting for use in clean rooms.

The Fact that the heat radiator is mainly in the long-wavelength range of the IR spectrum radiates, leaves the Heating device also for use in the field of medical therapy appear appropriate.

following is an embodiment of Invention with reference to the drawing explained. each other corresponding items or elements are in all figures with the same reference numerals Mistake.

In this demonstrate

1 an elongate, acting as a filament electrical resistance with a heat radiator to illustrate the basic principle of the invention,

2 a preferred embodiment of the invention in which the filament is enclosed on all sides by a heat radiator in the form of a tube,

3 a possibility for fixing the filament in a carrier,

4 a vertical section through a house wall with a filament introduced therein to form a wall heating,

5 a vertical section through carrier with more than one filament loop inserted therein,

6 a possibility for fixing the filament in the center of a surrounding protective jacket,

7 a preferred possibility for holding the resistance loop on the (later to be covered) surface of a carrier,

8th an application of the invention in the hot water and

9 an application of the invention as space heating.

1 shows to illustrate the basic principle of the invention, an elongated electrical resistance 10 , which is a heat radiator 11 assigned. The resistance 10 heats up when current is flowing. He is accordingly hereinafter also as filament 10 designated. The terms resistance 10 or elongated resistance 10 and filament 10 are used synonymously.

The heat of resistance 10 gets to the heat radiator 11 in particular transmitted by way of so-called. Heat conduction. This heats the heat radiator 11 , The heat of the heat radiator 11 can now by heat radiation 12 be delivered to the environment. The name as a heat radiator 11 This is due to the fact that it is intended and suitable for heat in the form of thermal radiation 12 (Radiation in the IR range) to give off, as is the case with heated bodies.

Send hot bodies known to be due to their temperature electromagnetic radiation out, the so-called temperature or heat radiation. The heat radiation includes in the spectrum directly to the red end of the visible light. The part of the spectrum from 0.7 μm up to a wavelength of 1000 μm as infrared spectrum.

The filament 10 (the resistance 10 ), for example, an alternating current with a voltage of 230 V flows through it. The use of direct current is also conceivable. As a filament 10 For example, carbon (carbon), in particular in the form of carbon fibers (carbon fibers) or carbon plates (carbon plates), into consideration. With a filament 10 in the form of carbon fibers this is usefully enclosed by an insulating jacket, for example made of silicone or the like. Carbon fibers have the advantage of great flexibility, allowing the filament 10 can be laid in almost any desired shape. When it comes to the flexibility of the filament 10 arrives, silicone is particularly suitable as insulating because of its great flexibility. Other materials with comparable flexibility are also contemplated for use as insulating sheath.

2 shows a preferred embodiment of the invention in which the filament 10 from a heat radiator 11 in particular in the form of a tube 13 or hose is enclosed on all sides. The following is for the filament surrounding the filament 11 throughout the term pipe 13 used. The term 13 It should include both the term tube in its usual use as well as the terms hose, in particular flexible hose, and sheath, in particular flexible or rigid metal sheath.

If the outer cross section of the filament 10 if necessary with a surrounding insulation 14 strong from the inner cross section of the pipe 13 deviates, so if the filament 10 is only slightly applied to the inner surface of the tube, it makes sense inside the tube 13 a thermally conductive medium 15 provided. As a thermally conductive medium 15 come both liquid and solid media 15 into consideration. An example of a liquid medium 15 is water, if necessary in a treated or treated Form, the chemical reactions with the surrounding pipe 13 avoids or at least reduces. An example of a solid medium 15 is sand or mordant, both optionally bonded with a thermally conductive binder, and the like. If the inner cross section of the pipe 13 in about the outer cross section of the filament 10 along with its insulation 14 matches, or if the filament 10 so laid is that this large area with the pipe 13 is in contact, is such a medium 15 possibly unnecessary.

filament 10 and pipe 13 are in the illustration in 2 in a carrier 16 , eg a house wall 17 or the like introduced. filament 10 and surrounding pipe 13 meandering in the carrier 16 so that the entire carrier 16 or a defined portion thereof of exactly one filament 10 in the form of an elongated resistor 10 is interspersed. Shown is a vertical section through the carrier 16 with the transverse to the longitudinal axis trimmed resistors 10 and pipes 13 ,

The heat radiator 11 and / or the thermally conductive medium 15 can also act as a neutral with a suitable choice of the respective materials at the same time to damage the filament 10 to exclude a risk to persons. For example, when hammering a nail into the wall 17 the filament 10 is hit and damaged, the current flows over the pipe 13 trained heat radiator 11 back to earth, if as a pipe 13z .B. a copper pipe or the like is used. If the pipe 13 is not electrically conductive, for example in a plastic pipe, it is preferred to the medium 15 in an electrically conductive form, eg water. If then the filament 10 damaged, the current flows through the medium 15 back to earth.

The respectively occurring at short notice greatly increased current is sufficient to trigger common electrical safety devices, so that the circuit with the filament 10 is disconnected from the mains and a personal hazard is no longer to get. Other, not shown variants for the heat radiator 11 are eg in place of the pipe 13 a jacket in a design as a spiral cable (not shown), a jacket as a web (not shown), as is known for example from the shielding of antenna cables, a jacket in the form of a flexible or rigid metal shell (also not shown), a jacket in Shape of a metal foil, with which the filament 10 wrapped (not shown), etc.

Radiant heaters 11 and coat can also fall apart spatially. For example, can be provided, the filament 10 in a jacket in the form of an electrically non-conductive tube 13 to arrange with water or other suitable, electrically conductive medium 15 is filled. Then the medium serves 15 So, for example, the water filling, as a heat conductor and as an electrical return to earth. As a heat radiator 11 is then arranged outside the jacket thermally conductive article, such as a metal plate, a metal foil (not shown) or the like provided. The shape of the shell is not subject to any limitations in terms of its geometry. So there are in particular round, oval, circular, rectangular and triangular cross-sections of such a jacket and any other conceivable cross section, with which the filament 10 all sides or at least on an exposed side can be covered, for example, a coat with semicircular cross-section, useful. The metal plate, foil or the like can also or instead of a then not required electrically conductive medium 15 take over the function as an electrical return conductor. For this purpose, the metal plate is grounded. In the same way is conceivable, the filament 10 between two plates made of a suitable material, of which either both or at least one as a heat radiator 11 acts to position. These are in one or both plates recesses for receiving the heating element 10 , For example, in the form of grooves or the like provided. In these recesses, the heating element 10 , either just from insulation 14 or additionally of a jacket in the form of a tube 13 or the like surrounded, inserted. Subsequently, the two plates are stacked and fixed together in this position. The plates with the filament contained therein 10 , possibly also several filaments 10 , can be used as a mobile heater, which can be leaned against a wall or attached to the wall in the manner of an image, for example, or as a stationary heater by being permanently connected to the wall, a ceiling or the floor. For improved installation and to improve the heat conduction is provided that the recesses, so for example the grooves 18 , in their dimension are such that the filament 10 with his isolation 14 or the surrounding jacket, eg in the form of the tube 13 , into which recesses must be pressed, as in 3 shown. The filament 10 is fixed in this way. In addition, there is a better heat transfer to the respective plate (the carrier 17 ), in which the filament is pressed. The recesses, so for example the grooves 18 , are dimensioned in their dimension so that by the (at least indirect) contact of the filament 10 with the respective plate results in the greatest possible heat conduction. These have circular grooves in their cross section 18 turned out to be optimal to the surface of the carrier 17 are positioned so that the center of the circular cross-section in the interior of the plate (the carrier 17 ) is located. The opening of the groove 18 is therefore smaller than whose maximum diameter, in turn, on the outer diameter of the filament 10 possibly with surrounding insulation 14 and / or with surrounding jacket, is tuned. In this groove 18 must the filament 10 be pressed to overcome the at least slightly smaller compared to its diameter opening. After the filament 10 into the groove 18 is pressed on all sides of the inner contour of the recess (the groove), so that there is a good heat transfer.

With a heat radiator 11 in the form of a plate or a foil can for better heat conduction to the heat radiator 11 a flexible Wärmeleitkonstruktion be provided in the heating conductor 10 is introduced. The heating conductor 10 is surrounded with the Wärmeleitkonstruktion so that it to about 2/3 on the heat radiator 11 facing side includes. The Wärmeleitkonstruktion ends on both sides of the heating element 10 in the form of a tab, which is used for better heat conduction or heating energy. The Wärmeleitkonstruktion is made of an electrically conductive material, so that the Wärmeleitkonstruktion in addition to a protection against mechanical damage as an electrical return conductor to the earth is usable. In addition, the material for the Wärmeleitkonstruktion is chosen so that it is flexible, on the one hand, the Wärmeleitkonstruktion together with the heating element 10 be able to lay in bows and the like and on the other hand to allow for workability with conventional tools, such as a notching of a portion of the Wärmeleitkonstruktion with a tin snips.

4 shows a representation of the application form according to 2 in a parallel to one through the through the filament 10 formed resistance loop, hereinafter also referred to as Heizfadenschleife defined plane executed vertical section through the wall 17 , You can see the meandering course of the filament 10 and the surrounding pipe 13 , The distance between the pipes 13 with each other, that is, for example, in the region of two mutually parallel sections of the tubes 13 , is selected depending on the desired heating capacity. The heating power is inversely proportional to the distance between the tubes 13 among themselves. In this way, there is a wall heating. The heater can of course also in floors or ceilings, so horizontal components, a brought. As a carrier 16 In addition to the components mentioned components and components of drywall, ie, for example, plasterboard, chipboard or prefabricated components, in particular made of aerated concrete or the like, and the like into consideration. In such devices, which are made substantially plate-shaped, the or each filament loop 10 in the in the 2 . 3 and 4 shown in the interior of the carrier 16 Thus, for example, in the gypsum compound for a plasterboard, in the liquid aerated concrete mass or in recesses in the form of slots, grooves and the like in the said components, which are then suitably closed again introduced. Such components are provided as needed and application with a remote from the main direction of the heat radiation thermal insulation, for example in the form of glass or rock wool and the like.

5 shows a representation of the application form according to 2 and 4 in which more than one filament loop 10 is used. The advantage of such an embodiment is that the temperature profile along the carrier 16 , ie along the height of the house wall 17 , can be adjusted individually. A conceivable setting is, for example, that the filament loop 10 near the ground, the highest heat output. Accordingly, this filament loop 10 subjected to the largest current. Higher filament loops 10 are successively applied each with a lower current, so that the filament loop 10 farthest from the ground, which gives the lowest heat output.

6 shows in a vertical section through a pipe 13 with filament contained therein 10 a way to fix the filament 10 in the center of the protective tube surrounding pipe 13 , Such a fixation is useful to different temperatures on the pipe 13 to avoid. Shown is the filament 10 with the surrounding insulation 14 , Starting from the insulation 14 extends a filament fixation 23 to the inner surface of the tube 13 , The filament fixation 23 is exemplified in a spoke-like manner. Of course, other forms of filament fixation 23 , eg disk-shaped, conceivable. In the spoke-like configuration of the filament fixation 23 In addition to four spokes, three, five or more spokes are also considered. It is important that the filament 10 in the center of the pipe 13 or at least substantially at the center of the tube 13 is fixed. The filament fixation 23 is in the tube at regular intervals 13 intended. The distances are chosen so that the filament 10 , in particular in the heated state, also in the section between two filament fixations 23 almost in the center of the tube 13 located.

In the case of attachment, not inside a wearer 16 , such as the house wall 17 but on the surface of the house wall 17 is at least a cover of the or each filament loop 10 through applied plaster 19 or the like provided. For such applications, it is provided that the filament 10 - as in 7 shown - In a support profile, in particular in a plastic profile 20 is arranged, together with the filament 10 and a possibly provided surrounding pipe 13 in a designated recess 21 in the carrier 16 , For example, slots in the masonry of old or new buildings, is introduced. The plastic profile 20 takes over the function as a heat insulator on the "back" of the filament 10 so on the inside of the vehicle 16 shrewd side. To the adhesion of the plaster to be applied to the cover 19 or similar material, it is envisaged that the plastic profile 20 with the filament contained therein 10 through a braid, eg a wire mesh 22 , is covered.

8th shows another preferred application example of the invention. Thereafter, one includes only schematically and in total with 25 designated water heating solar panels 26 , A heated by the collectors medium flows through the illustrated pipe circuit 27 and finally reaches a hot water tank 28 , in which the stored heat in the medium, for example by means of a heat exchanger in a known per se and therefore not shown manner to be heated to the hot water, which from an outlet 29 the hot water tank 28 can be deducted. The cooled in the heat exchanger medium passes through the circuit back to the collectors 26 and is reheated there by the heat in the heat exchanger 28 then leave again. The hot water preparation 25 is not limited to the production of service water. Likewise, the recovered hot water for a conventional underfloor heating or the like can be used.

When the medium passes through the collectors 26 No longer, for example due to lack of or insufficient solar radiation, can be warmed up so far that a predetermined temperature threshold is reached, this is the hot water preparation altogether in question. The heater according to the invention is therefore in the pipe circuit 27 integrated. This is a pipe section 30 provided in the pipe circuit 27 is inserted, in which a current flowing through electric filament 10 located. The filament 10 is of course all-round with a suitable insulation 14 enclosed. As the current flows, the filament heats up 10 so that the heat generated at the filament 10 flowing medium can be discharged. The heater according to the invention acts as a kind of additional heating and causes a temperature increase of the of the collectors 26 coming medium at least so far that the above-mentioned predetermined threshold is reached. The amperage with which the filament 10 can be acted upon by the temperature of the medium at the output of the collectors 26 be made dependent. This is a sensor 31 for detecting the temperature of the medium at the outlet of the collectors 26 intended. The respective measured value is sent to a control device 32 transmitted, which selects a suitable current depending on the measured value and the predetermined threshold, that is, depending on a resulting "heat deficit" and a power source 33 to which the filament 10 is connected, controls accordingly.

In 8th the special feature is shown that the pipe section 30 with the filament 10 in one of the collectors 26 parallel section of the pipe circuit is located. Furthermore, a first and a second valve 34 . 35 provided with the collectors 26 or the pipe section 30 in the pipe circuit 27 can be integrated. Both valves 34 . 35 are to be controlled by the controller 32 intended. So if so in such an arrangement of the pipe section in a parallel line section due to the probe 31 is determined that the heat supplied by the collectors is not sufficient for the hot water, activates the control device 32 the power source 33 so that the filament 10 Generates heat. At the same time, the first valve 34 closed, so that the medium is no longer through the collectors 26 flows, and the second valve 35 open, leaving the medium on the heated filament 10 flows along. If at the exit of the pipe section 30 another sensor is arranged, the control device 32 the current through the filament 10 control so that the required amount of heat for hot water production is optimally achieved. The control of the valves 34 . 35 does not necessarily have to be in a "fully open" or "completely close" form. Depending on the sensor 31 detected temperature are also useful intermediate stages in the control of the valves 34 . 35 conceivable.

9 shows another preferred application example of the invention. After that is the filament 10 in a tube 13 arranged, with the tube 13 is designed as a cylindrical tube section. Inside the tube is the filament 10 around a carrier tube 38 wound. To obtain a closed filament loop is the filament 10 eg in the interior of the carrier tube returned to the power source. The carrier tube 38 is preferably made of a low thermal conductivity material. In the space between the carrier tube 38 and outer tube 13 is a thermally conductive medium 15 , ie, for example, water and the like, as already described above. The surface of the pipe 13 heats up due to the heat conduction from the heated at current flow filament 10 through the medium 15 , The heated pipe 13 thus acts as a heat radiator 11 and gives the heat in the form of heat radiation 12 to the environment from. The overall construction is in a housing 39 housed one foot one-sided 40 having. This results in a total of 41 designated space heating, for example, by attaching the foot 40 on a house wall, in any desired position can be mounted. The cylindrical basic shape results in a space heating 41 which is optimal in terms of Abtrahlcharakteristik. In addition, it can be manufactured extremely economically. If necessary, several of the space heaters 41 be combined in groups.

Thus, the invention can be briefly represented as follows:
It is a heater with a particular designed as carbon fibers filament 10 indicated by either a pipe 13 , Hose or jacket is at least partially surrounded or by a pipe 13 , Hose or jacket and a thermally conductive medium contained therein 15 is completely surrounded and being either the pipe 13 , the hose or the jacket or the medium 15 are electrically conductive, so that in case of damage to the filament 10 the pipe 13 or the medium 15 can act as a return or neutral to earth, so that the heater meets relevant safety requirements.

10

Resistance / filament

11

Radiant heaters

12

thermal radiation

13

pipe

14

insulation

15

medium

16

carrier

17

housewall

18

groove

19

plaster

20

Plastic profile

21

recess

22

wire mesh

23

Heizfadenfixierung

24

---

25

Water heating

26

solar panel

27

Pipe circuit

28

Hot water storage

29

outlet

30

pipe section

31

probe

32

control device

33

power source

34

first Valve

35

second Valve

36

---

37

---

38

support tube

39

casing

40

foot

41

space heating

Claims (12)

Heating device with a provided for connection to an electrical power source filament ( 10 ), wherein the filament ( 10 ) consists of a carbon or a carbon compound or is designed as a carbon fiber and the filament ( 10 ) a heat radiator ( 11 ), characterized in that the heat radiator ( 11 ) made of an electrically conductive material and to function as a neutral or return conductor in case of possible damage to the filament ( 10 ) is provided. Heating device according to claim 1, wherein the heat radiator ( 11 ) a filament ( 10 ) partially or all-around surrounding profile, in particular a pipe ( 13 ) is. Heating device according to claim 2, wherein in the profile a thermally conductive medium ( 15 ) is located. Heating device according to the preamble of claim 1 or one of claims 1 to 3, wherein the filament ( 10 ) in one with a thermally conductive medium ( 15 ) filled tube ( 13 ), Tube or sheath is arranged and wherein the medium ( 15 ) as electrically conductive medium ( 15 ) and function as a neutral or return conductor in case of possible damage to the filament ( 10 ) is provided. Heating device according to one of claims 2 to 4, wherein the filament ( 10 ) in the profile, in particular in the tube ( 13 ), by means of a filament fixation ( 23 Fixed, in particular fixed and centered. Heating device according to one of claims 2 to 5, wherein the filament ( 10 ) in the interior of the pipe designed as a pipe section ( 13 ) around a support tube ( 38 ) and wherein the space between the carrier tube ( 38 ) and surrounding pipe ( 13 ) with a heat-conducting medium ( 15 ) is filled. Heating device according to one of the preceding claims, characterized in that it is used as additional heating in a pipe circuit ( 27 ) of a hot water preparation ( 25 ) or for integration into a pipe circuit ( 27 ) of a hot water preparation ( 25 ) is provided as additional heating. Heating device according to claim 7, wherein the hot water preparation ( 25 ) a sensor ( 31 ) for temperature detection and a control device ( 32 ), wherein the control device ( 32 ) the heater is activated as soon as the sensor ( 31 ) detected temperature falls below a predetermined or predeterminable threshold. Heating device according to claim 8, wherein the heating device comprises a shut-off device, in particular a valve ( 35 ) assigned by the control device ( 32 ) depending on the sensor ( 31 ) is opened, so that the heater is effective as additional heating. Method for operating a heating device according to one of claims 8 or 9, wherein the control device ( 32 ) by means of the sensor ( 31 ) continuously detects the temperature and activates the heating device as soon as the sensor ( 31 ) detected temperature falls below a predetermined or predeterminable threshold. Method according to claim 10, wherein the control device ( 32 ) upon activation of the heating device the shut-off device associated with the heating device, in particular the valve ( 35 ), opens or at least partially opens. Method according to claim 11, wherein the control device ( 32 ) in the activation of the heating device, a further shut-off device, in particular a further valve ( 34 ), closes or at least partially closes around the pipe circuit ( 27 ) to downsize.