DE3605780C1 - Tunnel furnace for baking raw graphite electrodes - Google Patents

Abstract

In the artificial carbon industry, which also includes the manufacture of electric graphite electrodes, the baking process of the raw electrodes has considerable importance as a central production stage between green production and graphitisation. The baking process takes place mainly in cassette ring furnaces. This type of furnace is very expensive in erection and also undergoes constant wear (caused by the moving fire). The baking process of pitch-bound materials leads to considerable emissions of hydrocarbon compounds. In the design of a tunnel furnace, according to the invention, for baking raw graphite electrodes, the baking-related and also economical advantages of the tunnel furnace are used and, by producing a 2-circuit smoke-gas circulation, the emission problem is solved, and the usable heat of the escaping hydrocarbon compounds is likewise converted in the furnace. A furnace of the present design renders unnecessary an E-filter smoke-gas disposal. It has an integrated post-baking chamber and can be designated as a self-baking tunnel furnace taking into consideration a foreign-matter requirement.

Description

The invention relates to a tunnel furnace for burning graphite raw electrodes. Raw graphite electrodes are semi-finished products from the Electrographite electrode production and according to the Technology in cassette ring ovens, or z. T. recently in Herd kiln burned. The standard technique, namely burning the electrodes in chamber ring furnaces represents a complex process step in electrode production. The investments for the creation of stoves are very high, and the stoves below are subject to high wear and tear from the migrating fire. The Fuel consumption is customary in the industry with 70 to 120 l heating oil EL specified per ton of electrodes. Although in a broader sense the burning of charcoal bodies as a ceramic process step is called, the electrode fire has its peculiarities. The fire control is difficult due to the burnout of the volatile hydrocarbons, that part of the binder (preferably a coal tar pitch) that doesn't bind medium coke can be converted. The escaping "fugitives" can lead to an undesirable self-ignition and thus cause a damaging temperature increase. The Problem is very complex and is only intended in this explanation be hinted at. Another very problematic feature of the chamber ring furnace are the emissions from the electrode fire.

According to the guideline values of TA-Luft, a flue gas care. The state of the art is ent supply via electrostatic filter and condenser separation. According to the principle of operation of e-filters, a residual amount can are not separated from hydrocarbon emissions, since only chargeable particles are effective with the e-filter principle. The gaseous hydrocarbons, which are still the first Leave the chimney, condense later and put the Limits of the e-filter.

Thermal afterburning (TNV) gives the possibility burn out all pollutants; however, operating one TNV as an alternative due to the high exhaust air volume a chamber ring furnace, a type of disposal that is up to 100% can make up the actual fuel requirement. The technology of a TNV has grown in the charcoal industry so far not been able to enforce.

The alternative burning method is burning in the bogie oven. With the bogie hearth furnace principle, facts are like lower ones Investments, short firing cycles, briefly less effort crucial for the introduction of this batch burning method be. Burning in the hearth furnace can than that American way of burning electrodes. The batch furnace presents other problems than the chamber ring furnace; however the emission problem remains the same. To mention However, the fact is that a batch operation with masses production of a continuous furnace not the Rank could run out.

In addition, the fuel consumption of the bogie hearth furnace is essential Lich higher than that of the chamber ring furnace.  

The claim to the invention is based on the existing status the technology in the operation of tunnel kilns in ceramics, mainly heavy clay.

As a task to be solved to make two main demands:

• 1. Use of the calorific value of the volatile hydrocarbons as constituents of the pitch binder or a tar-pitch mixture.
  In this case, a combustion curve-harmless Schwelgasab suction must be carried out over the degassing electrodes and a transfer to the high temperature area of the furnace.
  A complete burnout of the carbonization gases releases a quantity of heat that corresponds to the needs of the entire firing curve. This means that around 8% of the weight is lost from a ton of green electrode due to the separation of flammable hydrocarbon compounds. If one calculates the 80 kg pitch material due to its molecular structure (aromatics) with a low calorific value, it can nevertheless be expected that in a heat network: use of the burn-out materials and the resulting cooling heat, enough heat can be released to "burn the electrodes themselves"allow".
• 2. A furnace construction can be found and with one To operate the firing zone division so that only flue gases leave the oven that does not require disposal in accordance with the Air: organic substances in the production of hard fire coal, need more.

As a far-reaching requirement, the electrode annealing containers are to be designed in such a way that they yield a high yield of useful content per m ^{3 of} combustion chamber separated; here, a cassette usage factor is to be transferred from the chamber ring furnace analogously - the saggers of the bogie hearth furnace in use already provide the bridge. Although the saggers can in principle also be used in the tunnel furnace, they only offer an acceptable use if a few large electrode diameters pass through the furnace can be pushed.

In "mixed operation", the procedure according to the invention (see Chapter annealing containers).

The solution to the problem is a tunnel kiln for burning graphite raw electrodes, characterized in that that in contrast to known solutions for flue gas return guides, or flue gas recirculation - so well known DE-PS 26 43 406 (the "HM" tunnel furnace), or one Description in the manual "Oil Firing", author, W. Hansen, Springer Verlag, 2nd edition 1970, page 339 - not a flue gas recirculation is selected, but he According to the invention, a tunnel kiln is two independent of one another Has flue gas circulation.

It is proposed that in both flue gas circulations to maintain opposite heat exchanger principle in order some basic advantages of the ring furnace principle to take.  

The fact that it is easier in the tunnel oven due to its working principle to "get a grip on the problematic electrode degassing" should not go unmentioned:
While in batch operation (single-chamber, multi-chamber composite or bogie hearth furnace) the degassing takes place in a short period of time, approx. 10 to 15 hours and thus there is excess heat that has been handled in different ways, the problem with the chamber ring furnace does not arise this form, since the slow heating up results in a quasi dilution of the distillate. But even with the chamber ring furnace, only one chamber comes into the degassing (burnout), so that there are similar conditions.

In contrast, the tunnel kiln allows it to be moved of the feed material in different temperature and suction areas and consequently also allows easier handling of the carbonization gases to be burned out.

The tunnel furnace according to this application has an outer and internal flue gas circulation:

• A) The external flue gas circulation represents a self-contained circulation flow, which ensures the heat transport from a fall cooling area (zone f) to the heating zone (zone a) . When the hot, clean flue gases pass through zone "a", they become enriched with low volatile hydrocarbons. The temperature increase is specified at approx. 5 to 7 ° C / h, so that hot clean gas at approx. 400 to 500 ° C behind the lock 1 ( FIG. 1) enters the combustion channel and is drawn in the direction of the entrance gate enriches and leaves the combustion channel at approx. 150 ° C.
• Experience has shown that the electrode or stick temperature rises to 250 to 350 ° C. The transfer of the dirty gases, which are approx. 150 ° C, to the lintel cooling area (zone f) should be secured isothermally (tar condensation!).
• The dirty gas inlet in zone f is in front of lock 2 . The gas is moved in the direction of the main fire, burns out and leaves the combustion channel in front of the imaginary dividing line to the holding zone of the main fire. The transfer from zone f to zone a takes place in such a way that when entering the warming-up zone hot air or clean gas enters the combustion duct at the level of the wagon plateaus in order to ensure that the wagon floors are subjected to preferential heating in order to avoid undesired tar condensation. Appropriate measures must also be taken to ensure that the heat deficit resulting from the unequal mass ratios of "a" to "f" is covered. Here, a heat exchange offers itself, which results from the fact that part of the "excess" smoke gases leaving the tunnel furnace is used for the heat exchange for zone "a" . The intensive heat transfer must be ensured by means of circulation fans.
• B) The internal flue gas circulation is the actual supply of the main fire with the burnout gases from the electrodes and is composed of the following zones:
  • "b" = degassing area (generation area of the dirty gas).
  • "c" Pull the fox zone through the burnt-out flue gases coming from the main fire, which, as soon as they disturb the balance of the furnace (give off more heat than the temperature increase in line with the curve), leave the combustion channel. According to the process, the fox zone can only begin when fully degassed electrodes are inserted into it; a criterion for the length of zone "b" . On the other hand, the fox zone is to be dimensioned so long that only "clean" flue gases, after the dirty gases in zones "d" and "e" have been completely burned out, pass the area of the flue gas outlets. The higher-temperature part of zone "c" and zones "d" and "e" consequently represent the integrated afterburning chamber TNV of the concept. The driving curve (heating curve) has an electrode-characteristic image, which can be clearly seen from FIG. 1 - It represents the optimal firing curve for the electrode firing.
  • "d" - This zone is characterized by high heating rates of the trimmings, since degassed electrodes are usually heated up to 10 ° C / h. Since most of the electrode gap gases are to be burned out here, sufficient temperature (800 ° C and higher) and dwell time are necessary. The burnout must be ensured by suitable cross circulation.
  • "e" stop zone. This zone represents that area by giving the insert material time to equalize the temperature.
  • A lower exposure to dirty gas is provided here. The length of the holding zone also has the space required to allow a "flowing boundary" of opposing air flows: namely, here the two flue gas recirculation circuits affect each other. It must also be ensured that the external circulation flow is fed from the holding zone if necessary (special feature ef ') .
  • From Fig. 1 it can be seen that the zone "g" is the usual cooling zone as in other tunnel kiln curves and must be partitioned by means of lock 2 from the rest of the furnace. The hot cooling air generated in the cooling zone can be used as preheated combustion air as usual.
  • An excess of heat can be obtained from the flue gases that leave the furnace at approx. 600 ° C and the waste heat from the cooling zone "g" .

The firing curve, which is in accordance with procedural Ge design is very similar to the curve of a chamber ring furnace, only that it has a much shorter burning time allows time. But the curve can never be so short like a bogie hearth furnace - this requires the integrated Afterburner, and the "Neutralization Areas" of the individual zone transitions.

Claims (16)

1. tunnel furnace for burning graphite raw electrodes, characterized in that the tunnel furnace has two flue gas circulation circuits, an outer flue gas circulation circuit between the heating zone (a) and fall cooling zone ( f) and an inner flue gas circulation circuit within the degassing zone (b), the fox zone (c) , the heating zone (d) and the holding zone (e) is formed. 2. Tunnel furnace according to claim 1, characterized in that the circulation flows through two additional lift gates are secured. 3. Tunnel furnace according to claim 1 or 2, characterized in that the external circulation stream is formed as a heat exchanger circuit between the heating zone (a) and the fall cooling zone (f) . 4. Tunnel furnace according to claim 1 or 2, characterized in that the zone areas (a) and (f) have a horizontal ceiling. 5. Tunnel furnace according to claim 1 and 2, characterized in that additional heat exchangers are arranged in the heating zone (a) . 6. Tunnel furnace according to claim 1 or 2, characterized in that the degassing zone (b) is equipped with a double ceiling to form a dirty gas collecting space. 7. Tunnel furnace according to claim 6, characterized in that the degassing zone (b) is formed with a domed ceiling and separation of chokes. 8. Tunnel furnace according to claim 1 or 2, characterized in that dirty gas lines after different ignitability or different calorific value of the dirty gas in the high temperature range (d, e,) are guided. 9. Tunnel furnace according to claim 1 or 2, characterized in that the burners are designed as multi-fuel burners, which introduce the dirty gas and as a backup burner can act. 10. Tunnel furnace according to claim 1 or 2, characterized in that several flue gas foxes are arranged in the neutral furnace atmosphere area between the degassing zone (b) and the heating zone (d) . 11. Tunnel furnace according to claim 1 or 2, characterized in that that by a ceiling burner where the poker holes are arranged so that discharged dirty gases on the Bump the end faces of the annealing containers.   12. Tunnel furnace according to claim 1 or 2 with a lintel cooling device in which the colder dirty gases from the heating zone (a) can be blown in front of the cassettes, preferably in each case from several positions. 13. Tunnel furnace according to claim 1 or 2, characterized in that, if necessary, hot air from the holding zone (e) can be drawn to the lintel cooling zone (f) . 14. Tunnel furnace according to claim 1 or 2, characterized in that that it can be used with universal cartridges from temperature solid steel, with the cassettes out Longitudinal parts with trapezoidal profile, smooth end walls and without Soil are made and can be turned. 15. Tunnel furnace according to claim 1 or 2, characterized in that that the kiln car plateaus are designed so that, determined through the cassette width, along the direction of travel Um roller sections remain free. 16. Tunnel furnace according to claim 1 or 2, characterized in that the kiln car plateaus are designed so that the upper Longitudinal base plates for guiding the cassette lengthways have sheets.