DE1091591B - Bonnet blank annealing furnace with heating and protective gas hood - Google Patents

Description

Hooded blank annealing furnace with heating and protective gas hood The invention relates to a hooded blank annealing furnace with heating and protective gas hoods, which are used to enlarge the heat-transferring surface is corrugated or ribbed.

In the known hood annealing furnaces with circulating heating that work so "that when glowing, for example band rings, under a protective gas hood through a Circulator protective gas is circulated as a heat transfer medium at high speed, takes place the heat transfer in such a way that the directly or indirectly heated protective gas hood the heat directly through radiation and / or indirectly through the circulating protective gas releases to the annealing material.

The upper annealing units are used without any special precautions heated faster than the lower ones. Since now all parts of the annealing material are required Subject to the annealing process, i.e. at least a fixed time at a certain temperature must be exposed, the time required for the annealing process is increased considerably, so the output of the furnace is greatly reduced.

It has also already been proposed, but is not yet part of the state of the art, to arrange control elements for the protective gas flow in such a way that more heat is supplied to the lower annealing material units, thereby promoting more uniform heating of all the annealing material units. Since it was found that the temperatures of the circulating gas were very different at different points in the circulating system, the circulating speed was increased considerably and the heating surface of the protective gas hood was increased. This measure resulted in better temperature compensation in the circulation system .

The invention is based on the task through appropriate training the protective gas hood the same temperatures of the protective gas everywhere in the circulation system to create and thus to achieve more uniform and faster heating of the annealing material.

It is known in the reduction of poorly thermally conductive, powdery Metal connections in annealing boxes, the annealing boxes for a better supply of heat to pull through the powder with heat-conducting ribs. Come on, those ribs the powder straight to the plant.

It has also already become known in Hau: benglühöfen annealed material containers to be arranged, which are flowed around or through the protective gas flow in a spiral should, with only suction or pressure of the circulator as a means to achieve this flow was used, in one case an additional one arranged in the vicinity of the circulator Guide ring. These means could not achieve the desired helical flow. It has also already become known to have wrought-iron incandescent material cylinders with vertical to form corrugated walls and the protective hood of hood annealing furnaces to achieve to provide an enlarged heating surface with vertical waves or ribs.

The invention is based on such an arrangement and proposes plan to put ribs on the inside and outside of the protective gas hood, which are attached to on the outside essentially .vertically and on the inside in a helical shape are arranged such that they helically the rising inert gas to lead. With this arrangement, not only the heat-absorbing and the heat-emitting The area of the hood is increased, but at the same time the rising shielding gas flow becomes out and its path increased along the heat-emitting inner wall of the protective gas hood. The shielding gas flow is therefore on its way before entering the respective convectors can absorb more heat than any of the arrangements mentioned so far. Through the Arrangement, a higher cooling effect is achieved at the same time as cooling.

In addition to these thermal advances, there is one Increasing the stability of the hood, which is of considerable importance. Both Previously common hoods, which have a considerable weight at a height of about 3 to 4 m occurred after a few annealing processes as a result of the considerable weight load in the heated state, creasing and deformation of the lower part of the hood, what now effective due to the rib arrangement, in particular by the ribs, which are arranged differently on the outside and inside, are completely avoided.

In that the outer surface in relation to the inner surface of the protective gas hood Choosing different sizes by changing the number and / or size of the ribs it is possible to achieve any desired heat absorption and release. By Change in the slope and / or the distance and / or the number of inner ribs Depending on the height of the hood, it is possible to determine the flow of protective gas in detail to influence during his way. The heat transfer and the rate of climb can also be controlled in that the rib cross-section is dependent changes from the height of the protective gas hood. The inner ribs are taking advantage of the direction of the ascending. adapted circulated protective gas emerging from the diffuser. It is also thought to arrange ribs only in the lower part of the protective gas hood, as more attention is generally paid to the heat supply in the lower part must be than the heat supply in the upper part.

Double-walled protective gas hoods are known in which the protective gas is heated when ascending between the outer and inner wall and at the upper end the inner wall, which ends just below the hood lid, with its highest temperature exit. The disadvantage of these designs is that the upper annealing units are heated faster than the lower ones.

According to the invention, even with multi-walled protective gas hoods, at least one of the hoods with ribs and / or waves and the outer wall of the outer hood always be provided with vertical ribs. By reducing the height of the inner hood and / or by making openings in this, the flow of protective gas can be considerable already deflected down below the lid and thus the lower annealing units a larger amount of heat can be supplied.

Embodiments of the invention are based on the drawings described. In the drawings represents.

Fig.l an embodiment according to the invention of a single-walled protective gas hood, partly in section, in a hooded blank annealing furnace, FIG. 2 shows an inventive Embodiment of a single-walled protective gas hood, partly in section, with internal ribs with an upwardly increasing slope, FIG. 3 shows an embodiment according to the invention a single-walled protective gas hood, partly in section, with inner and outer ribs on a part of the protective gas hood, Fig. = 1 an embodiment according to the invention a double-walled protective gas hood, partially in section, FIG. 5 shows an inventive Embodiment of a partially double-walled protective gas hood, partially in section.

1 shows a hooded blank annealing furnace which can be heated directly or indirectly and into which a protective gas hood according to the invention is inserted. The amount of heat introduced into the heating hood 1 is transferred directly or indirectly to the protective gas hood 2 by radiation. The protective gas is circulated by a circulator 3 under the protective gas hood 2. Annealing units, e.g. B. sheet metal coils 4, 4a and 4 b, are separated from each other by convectors 5 and 5 a. The protective gas gives off its heat in the circuits A, B and C through the convectors 5, 5a and over the upper surface of the upper collar 4b to the annealing material and passes through a suction space 6 formed in the middle of the collars 4, 4a, 4b back to the circulator 3. For the proper guidance of the protective gas flow, the diffuser 7 is finite (in cross section) lamellae 8 designed as logarithmic spirals. About a designed as a guide member outer wall 9 of the diffuser 7 z. B. a tangential outlet and a certain angle of inclination of the protective gas flow is achieved.

The protective gas hood 2 consists of a sheet metal jacket 10 and a cover 11. On the inside of the sheet metal jacket 10, ribs and / or waves 12 are welded or in another suitable manner so that an effective heat transfer from the jacket 10 to the spiral ribs and; ' or waves 12 takes place. Depending on the number and / or the shape and / or the other type of design of the ribs and / or corrugations 12, the heat transfer of the surface can be increased as desired and, moreover, the circulated protective gas flow can be directed by a vertical or spiral arrangement. Its angle of inclination depends on the outer wall 9 of the diffuser 7, which is designed as a guide element. This enlargement of the heat-emitting inner surface results in a corresponding enlargement of the heat-absorbing outer surface of the protective gas hood 2. It is achieved in the same way as with the inner surface by ribs and / or corrugations 13, which are preferably arranged vertically. As can be seen from FIG. 1, ribs and / or corrugations 13 can be provided, which extend up to the cover 11 and / or end at the edge of the cover 11. With the enlargement of the outer surface of the protective gas hood, the cooling effect when cooling the annealing insert is advantageously also increased and the stability of the thin-walled protective gas hood is increased considerably.

By enlarging the effective inner and outer heating surfaces the protective gas hood 2 and the more favorable ratio of the heating surfaces achieved therewith to the heat-absorbing surface of the annealing material as well as the supporting control of the protective gas flow due to the inclined ribs and / or waves 12 a particularly fast and even heating of the material to be annealed is achieved.

Since in hood-type blank annealing furnaces without control of the protective gas flow, the The upper annealing units can be heated faster than the lower ones, as shown in FIG shown, the slope of the inner ribs 12 can be changed so that in the lower Part of the hood, i.e. where the larger amount of heat is required, a larger one Heating surface is available. The same purpose can, as shown in Fig. 3, achieve that the inner ribs 12 and the outer ribs 13 only in part the hood, e.g. B. only in the lower part, are attached or that the number of ribs is decreased in the upper part.

They are double-walled protective gas hoods for use in hood-type bright annealing furnaces, but without control of the protective gas flow, known. Here is the treasure gas heats up when climbing between the outer hood 14 (Fig. d) and the inner hood 15 and occurs at the upper end of the inner hood 15, which ends just below the hood cover 11, with its highest temperature. According to the invention are for enlargement the heating surface on at least one hood, z. B. on the inner wall the outer hood 14, spiral-shaped ribs and / or waves 12 attached, and the outer wall the outer hood 14 is provided with vertical ribs 16. As in this version too the upper part of the material to be annealed is heated faster than the lower and thus one Uneven heating occurs, can, as Fig. 5 shows, for faster heating of the lower parts of the material to be annealed and slower heating of the upper parts of the material to be annealed, overall in other words, to achieve a more uniform and thus overall faster heating even with the double-walled hood, only a part of the at least one hood Heating surfaces provided with spiral ribs and / or waves 12 and on the outer wall the outer hood 14 vertical ribs 16 are attached. The protective gas flow is then z. B. already deflected downwards at half the height of the hood 17, and for heating of the lower annealing units, while only a smaller part uses the upper ones Annealed units coated and heated, so that a more even heating of the entire annealing material takes place.

Apart from the illustrated exemplary embodiments, it is also there intended to increase the surface area of the hoods or a part of them to be achieved by a different shape.

Claims (7)

PATENT CLAIMS: 1. Bonnet annealing furnace with heating and protective gas hood, which are corrugated or ribbed to increase the heat transferring surface is, characterized in that on the inside and outside of the protective gas hood (2) Ribs are attached, the outer ribs (13) being essentially perpendicular run and the inner ribs (12) are arranged helically, in such a way that they lead the rising protective gas in a helical manner. 2. Hood bright annealing furnace according to claim 1, characterized in that the outer surface in relation to the inner surface the protective gas hood (2) by the number and / or size of the inner (12) or outer ribs (13) is different in size. 3. hooded blank annealing furnace according to claim 1 or 2, characterized characterized in that the slope and / or spacing and / or number of the inner ribs (12) the height of the protective gas hood (2) are adapted. 4. Hood blank annealing furnace after a of claims 1 to 3, characterized in that the rib cross-section of the height the protective gas hood (2) is adapted. 5. hood-type bright annealing furnace according to one of the claims 1 to 4, characterized in that only in the lower part of the protective gas hood (2) Ribs (12, 13) are arranged. 6. Hood blank annealing furnace, characterized in that that when using multi-walled hoods at least one of the hoods according to one of the Claims 1 to 5 is formed. 7. hood-type blank annealing furnace according to claim 1 to 6, characterized in that the protective gas hood, as known per se, is double-walled is formed and the inner edge (15) well below the lid (11) of the Outer hood (14) ends or there with openings for the passage of the circulated protective gas is provided. Considered publications: German Patent Specifications No. 967 077, 866 493; Austrian Patent No. 42 501; U.S. Patents No. 2 529 609, 1 940 948.