DE3620203A1 - HEATING ELEMENT - Google Patents

Abstract

In order to improve the flexibility and ease of assembly of a heating element, it is proposed that the latter is not made of one and the same material but that at least the connection piece is made from another electrically-conductive but heat-resistant material.

Description

The invention relates to a heating element, in particular a such for the electrical heating of industrial furnaces.

Under the name "industrial furnace" each type of continuous and discontinuous industry oven understood. For example, tunnel and roles ovens, bogie hearth furnaces, chamber furnaces, hood furnaces, for example for the ceramic industry but also shaft furnaces, Billet heating furnaces, forging furnaces for the metal industry and furnaces for the glass industry. A limitation in this respect does not exist.

The invention is preferred to achieve heating elements higher furnace temperatures, especially above 1200 ° C, preferably directed above 1500 ° C.  

Various such heating elements are known in the prior art. Those made of molybdenum disilicide (MoSi ₂ ) are preferred, in particular because of their good resistance to oxidation at high temperatures. Among all metallic materials with good electrical and thermal conductivity, molybdenum disilicide is considered to be particularly suitable for the application mentioned, although heating elements made from it also have disadvantages.

MoSi ₂ is an intermetallic, brittle material from which molded articles such as heating elements are not only difficult to manufacture, but also in which the finished products are very difficult to handle. Especially when used in industrial furnace construction, where the heating elements must be guided through the furnace wall and fastened, it often happens that heating elements are destroyed by striking the furnace housing.

In particular, to reduce brittleness, cermet Materials made of molybdenum disilicide with a relatively light weight melting glass known. Above 1500 or 1600 ° C melts the glass component, which is up to 20 volume percent can make out what a certain plastic Ver malleability results.

Upon contact with the ambient air, a surface layer of glass forms and a thin layer of molybdenum disilicide with a lower silicon content (Mo ₅ Si ₃ ). This "protective layer" adheres extremely well and does not come off automatically if the heating element is cooled. However, if the heating element then remains in a temperature range below 800 °, in particular in a temperature range between 600 and 900 ° C, the protective layer will dissolve and in particular no new protective layer will be formed. There is a so-called "molybdenum disilicide plague", a peeling off of individual layers gradually with intermediate oxidation, whereby the element becomes thinner and thinner until it finally breaks.

The heating elements usually consist of the actual one Heating wire (the heating loop) and preferably on it welded fittings. The actual heating part has a smaller diameter than the An final part, so in the latter due to the increased spec fish electrical resistance lower temperatures can be set.

The diameter of the heating part is normally 6 up to 9 mm, during that of the connecting parts between 12 and 18 mm.

The shape of the heating part can be any, for example U-shaped or meandering, bent at right angles or curved, in any case, however, there are two connections per heating element pieces necessary.

As a rule, the heating elements are attached in such a way that with their fittings in the furnace wall, the Insert furnace masonry, and only the heating part in the too heating furnace space protrudes.

Accordingly, there is a difference between inside and outside area of the masonry in which the connectors are spaced to each other, a temperature gradient from the inside  to the outside.

For example at a temperature of the heating conductor of 1400 ° C is then the above critical Temperature range between 600 and 800 ° C approximately in the Middle of the longitudinal extent of the connecting pieces, and thus in the masonry.

The above-mentioned molybdenum disilicide plague then forms moves out here. The heating elements often break in this Area and then need to be replaced, taking care their removal or replacement is relatively difficult can represent if there is a complete break has come.

Apart from the high cost of a new heating element this also creates a reduced lifespan increased repair effort.

One tried, with a kind of adapter, with the the connection ends are aligned parallel to each other, in so far as a relief to create the described Difficulty of oxidation in the temperature range below However, 800 ° C cannot be eliminated with it.

In this respect, the invention is based on the object Offer heating element that has a longer lifespan points and in particular also in the temperature range below 800 ° C is stable. Furthermore, the heating element should be so designed tet that a lighter and cheaper Aus exchange and easier handling overall light becomes. After all, the heating element is supposed to be in one  preferred embodiment can also be designed so that Connections with neighboring heating elements easier through are feasible.

The invention is based on the knowledge that an elec trical heating element, especially one made of molybdenum Silicon compounds, not necessarily one and the other must consist of the same material; there are rather possibilities there, such a heating element also with connecting parts to connect from other materials.

In this respect, the invention proposes an electric heating element consisting of a heating part and a connection part before, wherein the heating part and the connecting part at least partially wise from different, electrically conductive materials consist. The connector can either with a Section, preferably abge with its the heating part turned rear free end section or even completely made of a different material than the heating part consist.

The connection between the heating and connecting part can done either directly or indirectly, already a medium for reasons of manufacture and manageability bare connection, for example through an intermediate piece, is preferred.

In this way, in particular in the oven wall or section arranged to the brickwork, namely the connection section of the heating element, from a Material are produced, which is also electrical is conductive, but compared to thermal and atmospheric  Load less sensitive than the material of the heater partly is.

Especially with one made of molybdenum-silicon compounds, in particular molybdenum disilicide existing heating element According to the invention, only the heating part and given if a section of the adjoining Connection part consist of molybdenum disilicide, while the rear, free connector from a different Material can exist.

This is done with a corresponding constructive design especially the "critical temperature range" for Molybdenum disilicide, namely the temperature range below half 800 ° C, especially between 600 and 800 ° C the section not made of molybdenum disilicide of the connecting part relocated so that the above described level corrosion (molybdenum disilicide plague) no longer occur can.

In addition, the embodiment in particular offers in which the heating part and possibly a first section of the connector with the rest of the connector a detachable clamp or screw connection is connected is the decisive advantage that the com plette heating element needs to be replaced, but only its front section, which carries the heating part, while the rear connector section is reusable is.

This not only makes the expensive material for the heating part saved, but especially in the fragile warehouse  cut the heating element, for example in the wall or the ceiling of an industrial furnace, is now a section arranged of the heating element, which is also temperature durable but much less sensitive to breakage than the part of the heating element protruding into the furnace. To this extent there is a risk of the heating elements being destroyed due to assembly, but also due to transport the shorter component length, significantly reduced.

The preferably detachable connection between the connection part or the corresponding section of the Connection part and the heating part can on most different Way.

In an advantageous embodiment of the invention a clamp connection from a cylindrical Rohrab cut suggested in one open end of one expanding outwards and projecting outwards Clamping sleeve is arranged via a pulling device against the cylindrical pipe section under fixing a heating part or connection inserted into the clamping sleeve section can be determined. For example via a pull rod, which on its the clamping sleeve facing end has an external thread that in a internal thread arranged in the clamping sleeve can be screwed is, the end position of the tie rod and clamping sleeve specified by appropriate flanges on these components becomes. On the outwardly projecting section of the drawbar the electrical connection can then be made.

Of course, a multitude of white are available to the expert other connection types are available, for example one Screw connection.  

This can be made of a different material closing piece relatively thin-walled and thus easily formed be, which further favors the overall manageability.

A large number of works are also available to the expert substances available from which he be the connector can produce connecting part section.

In an advantageous embodiment of the invention a temperature resistant, preferably in temperature steel resistant to 1200 ° C suggested, for example a chrome-nickel steel. Will be exemplary a chrome-nickel steel quality with 18 to 25 weights percent chromium and 8 to 20 weight percent nickel beat. Instead of nickel, for example Cobalt can be used as an alloying element to achieve the desired temperature resistance of the steel.

Due to the inventive design, bes seren manageability and easier assembly and the Possibility of using cheaper and easier Materials also have a lower electrical / heat consumption lust reached.

Because with heating elements according to the prior art, the full consist of molybdenum disilicide, the heat conductor one third and each connection end another third the cost, arises from the invention appropriate training in addition to a cost advantage the savings mentioned through longer life and  lower breaking sensitivity of the components.

The inventive design of a heating element enables it in an advantageous embodiment of the Invention also, the connecting part or connection subsection made of a different material, to train so that at a distance in front of his free rear End an electrical connector is formed. This connector is preferably arranged so be that when installing the heating element in a Stove wall or ceiling still runs in the wall or ceiling, so that the electrical connection to the adjacent connector piece within the furnace wall or the furnace wall work takes place. This allows the electrical and thermal losses can be further minimized.

As an additional measure to promote the aforementioned For the purpose of the invention provides that the connecting part or Connection section is designed so that it on his free rear end with an electrical and thermal insulating component, for example a refractory ceramic insulating stone, can be sealed.

So both star and series connections of the various heating elements easily made will.

Further advantages of the invention result from the others Claims and the other description documents.

The invention will be described in more detail below with reference to the drawing explained. The drawing shows a schematic view in  

Fig. 1 shows a heating element according to the prior art

Fig. 2 shows an embodiment of a heating element according to the invention

Fig. 3 shows a clamp connection of a heating element according to the invention

Fig. 4 shows a circuit arrangement for a plurality of heating elements according to the Invention

Fig. 5 shows a further embodiment of a circuit of a plurality of heating elements according to the invention.

The heating element shown in FIG. 1 according to the prior art consists of a U-shaped bent heating part 10 with two legs 12, 14 and two connecting parts 16 , 18 connected to them , at their free ends 20 , 22 (not shown) electrical connections can be connected.

The heating element is made entirely of molybdenum disilicide. The heating part 10 has a diameter of 6 mm, while the connecting parts 16 , 18 each have a diameter of 12 mm.

The transition area between the legs 12 , 14 of the heating part 10 to the connecting parts 16 , 18 is designed to widen conically. The heating part 10 is welded to the connection part (the connection parts 16 , 18 ).

In Fig. 2, a first embodiment of a heating element according to the Invention is shown. This in turn has a U-shaped heating part 30 with two leg sections 32 , 34 , which pass analogously to the embodiment according to FIG. 1 via a conically widening section 36 , 38 in the connecting part 40 , 42 consisting of two parts.

The connecting parts 40 , 42 are each formed in two parts, the sections 44 , 46 facing the heating part 30 , like the heating part 30, made of molybdenum disilicide, while the rear free connecting part sections 48 , 50 consist of a chrome-nickel steel of the quality 25/15 .

The sections 44, 46 of the connection parts 40, 42 are electrically conductively connected to the rear connection sections 48 , 50 via a clamp connection 52 , 54 in each case.

The external electrical connections are the same as for the State of the art.

The arrangement is chosen so that at a temperature of the heating part 30 of approximately 1400 ° C, the rear connection portions 48 , 50 are arranged in the part of the furnace wall in which temperatures below 1000 ° C prevail. The rear connecting part sections 48 , 50 made of chromium-nickel steel thus also lie in the region in which the heating element has a temperature of 600 to 800 ° C., that is to say in the region critical for molybdenum disilicide components. This temperature range does not affect the strength of the steel in any way.

With a consumption of the heating element, which thus consists of the heating 30 and the front connector sections 44,46 here, only these parts need over the terminal connections 52, released 54 and a new insert on the remaining rear connector sections 48, are set 50th This results in considerable cost advantages. In addition, the rear part of the heating element used by mechanical loads is made of mechanically less sensitive steel, so that overall there is less brittleness to breakage.

In Fig. 3, a clamp connection according to the invention is provided. The connecting part 60 consists of a cylindrical tube section 62 , into the front free end 63 of which a clamping sleeve 64 protrudes, which widens toward the free front end 63 of the tube section 62 and protrudes outwards, and has an end-side circumferential flange edge 65 . At its rear end, the clamping sleeve 64 has a tapered section 66 with an internal thread into which a pull rod 68 projects, which has at its front free end 70 an external thread corresponding to the internal thread of the clamping sleeve.

The pull rod 68 protrudes rearward through a cylindrical opening in spaced intermediate walls 72 , 80 of the pipe section 62 and has an outside flange 74 between them. The outside electrical connection is provided at 76 .

By screwing the pull rod 68 in relation to the slotted clamping sleeve 64 , for example, the latter is pulled backwards (arrow direction F ) and clamps the front connecting section 76 of a heating element 78 firmly. The heating element 78 can be released and then removed by rotating the pull rod 68 in the opposite direction and thus releasing the clamping sleeve 64 relative to the latter. The flange 74 is supported on the intermediate walls 72 , 80 .

In Figs. 4 and 5 different heating elements according to the invention in series (FIG. 4) or star connection (Fig. 5), wherein a respective elec tric connection 81 of two heating elements in the region of the rear corresponding and respectively shortened connecting pieces 48, 50 of the heating elements takes place. The arrangement of the heating elements is such that the corresponding connection area 81 is arranged within the furnace wall (not shown). For better insulation, a refractory ceramic insulating block 82 can be placed from the outside.

Instead of the U-shaped heating elements shown can naturally also differently shaped heating elements the way proposed according to the invention are designed. For example, double hairpins are used here Heating parts or angled heating parts called.

Claims (14)

1. Electrical heating element, consisting of a heating part ( 30 ) and a connecting part ( 40 , 42 , 60 , 76 ), characterized in that the heating part ( 30 ) and the connecting part ( 40 , 42 , 60 , 76 ) at least partially different, electrically conductive materials exist. 2. Heating element according to claim 1, characterized in that the connecting part ( 40 , 42 , 60 ) with its heating part ( 30 ) facing away from the free end portion ( 48 , 50 , 60 , 76 ) consists of a different material. 3. Heating element according to claim 1 or 2, characterized, that the heating and connecting part directly with each other are connected. 4. Heating element according to claim 1 or 2, characterized in that the heating part ( 30 ) and optionally an adjoining first section ( 44 , 46 , 76 ) of the connecting part ( 40 , 42 , 60 , 76 ) via an intermediate piece ( 52 , 54 , 64 ) are connected to the connecting part (section) ( 48 , 50 , 60 , 76 ). 5. Heating element according to claim 4, characterized in that the heating part ( 30 ) via a releasable clamping connection ( 52 , 54 , 60 , 64 ) with the connecting part (section) ( 48 , 50 , 60 , 76 ) is connected. 6. Heating element according to claim 4, characterized, that the heating part via a screw connection with the Connection part (section) is connected. 7. Heating element according to claim 5, characterized in that the clamping connection ( 52 , 54 , 60 , 64 ) consists of a cylindrical tube section ( 62 ) with a conically widening outwardly projecting and outwardly projecting clamping sleeve ( 64 ), which over a pulling device ( 68 ) can be fixed against the cylindrical tube section ( 62 ) by fixing an inserted heating section or connecting section ( 76 , 78 ). 8. Heating element according to one of claims 1 to 7, characterized in that the connecting part (section) ( 48 , 50 ) is provided at a distance from its free rear end with an electrical connector ( 81 ). 9. Heating element according to one of claims 1 to 8, characterized in that the connection part (section) ( 40 , 42 , 60 , 76 ) and / or the intermediate piece ( 52 , 54 , 64 ) made from a different material temperature-resistant material exist. 10. Heating element according to claim 9, characterized in that the connecting part (section) ( 40 , 42 , 60 , 76 ) and / or the intermediate piece ( 52 , 54 , 64 ) from a temperature constant, preferably in the temperature range up to 1200 ° C temperature resistant Steel. 11. Heating element according to claim 10, characterized in that the connecting part (section) ( 40 , 42 , 60 , 76 ) and / or the intermediate piece ( 52 , 54 , 64 ) made of a chrome-nickel steel or chrome-cobalt steel consists. 12. Heating element according to one of claims 1 to 11, characterized in that the heating part ( 30 ) consists of a molybdenum-silicon alloy, preferably MoSi ₂ . 13. Heating element according to one of claims 1 to 12, characterized in that the connecting part (section) ( 40 , 42 , 60 , 76 ) is so formed that it has at its free rear end with an electrically and thermally insulating component ( 82nd ) is sealable. 14. Heating element according to claim 13, characterized in that the component ( 82 ) is a refractory ceramic Iso lierstein.