DE1533845C - Water-cooled furnace blow mold - Google Patents

Description

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The invention relates to a water geling body should now be applied to the interior of the blast furnace cooled, high-facing side forming the end of the wind tunnel, d. H. towards the blow molding tip, ofenblasfonn, which is designed as a hollow body with an uninterrupted ring-shaped cooling water ring-shaped cavity, with an outlet slot received. So the cooling water should this cavity up close to the blow mold 5 from this slot in the form of an annular tip Reaching the cooling water displacer in the eye of the steel and onto the inner wall is arranged, furthermore at the point of the blow mold the blow mold in the region of the blow mold tip from the end of the blow molding, a close and a meet "and create a cooling effect here .. After Discharge for the cooling water are provided in such a way that the impact is the annular cooling means the cooling water deflected between the displacer ίο jet to two sides, so that he the body and the blow cooling water distribution body adjacent to the wind tunnel on both sides from the outside Form wall formed space and then after flows around. At the deflection that lies away from the blow mold tip The cooling water collects in the area of the blow mold tip at the end of the blow mold between the Verdrängerkö.rper and the outer in an annular space to which the Kühlwasserablei blow mold wall The space formed flows through and is connected to the water, so that the cooling water of at the wall of the annular space between ver exits from the blow mold, pusher body and blow mold wall with. Grooves, grooves, In another embodiment according to FIG or channels. German patent 719 138 is the cooling water

There are already water-cooled blast furnace distribution bodies not as hollow bodies, but as one become known, in which the cooling water 20 times formed as a single cylinder surface, but also inlet is led to the tip of the blow mold. The one here is supposed to first put the cooling water in the outer ring disadvantage This known design consists in the space flowing to the blow mold tip and, at the same time, essentially in the fact that an undefined flow is supported by the heat-insulating effect of the tion of the coolant inside the blow mold on the cooling water distribution body, as cool as possible up to the way up to the outlet pipe on the outside and then to the inside of the ring. Attempts have also already been made to excavate the improvement space that is adjacent to the wind tunnel to flow back through this known design.

lead by redirecting the entry all this from the German patent specification rohrcs in the area of the blow molding tip, around a 719 138 known designs or construct tangentials Achieve flow. However, the underlying idea is to promote a ring, that also with this design a moderate jet of cooling water on the inner wall of the to generate even water distribution with a sufficient blow molding tip. Precisely from this results Flow velocity at the hoclnvürmebe-i but in practice the main disadvantage, the burdened places cannot be reached. What can be seen in it is that in the area of the blow molding consequences are the well-known damage caused by excessive, indefinable eddy currents through the Heating caused by insufficient cooling to through-beam. These eddy current burners to lead. . form mations. even when redirected to the

From practical experience it is known that the sharp edge of the cylinder with the maximum stress on the blow mold in the case of an area of the embodiment. emotion. takes place with liquid iron, namely 40 from the German utility model. 1 819 030 is especially in the area of the blow mold tip. In order to continue to become known a blast furnace blow mold, To master this condition, the cooling system has to consist of two hollow bodies, done at high water speeds. On- whereby the outer hollow body is the actual Blasbauend Based on this knowledge, there is already a nozzle and the inner hollow body a rotatable one Construction has been proposed in which the 45 use to change and adjust the cooling water in the forced passage through one around the triüsqu cross section of the nozzle forms. While the Blow mold wound pipe coil is guided. The outer cavity after the blow molding tip over the required Apart from the construction effort, because of the entire length, it tapers conically, in the area of the blow pressure loss a high expenditure of energy. tip itself but roughly angled rectangular

Special constructions of the aforementioned type S ⁰ . is, so that a substantially rectangular hollow 'are from the German patent 719 138 beraum with corresponding. Wall became known to the rotatable. The blast furnace blow mold has an insert placed in front of it, the insert widens annular hollow through which the cooling water flows towards the blow mold tip to form a correspondingly conical space. In this. A cavity is a cooling water- Aach is located in the area of the blow mold distribution body, which with a point creates an undefined water flow, which is necessarily subject to eddies, for introducing the cooling water into the interior, which is not similar to that of the likewise hollow Cooling water distributor is able to bring about sufficient cooling, is provided with a body. Furthermore, such an exit is in the invention from an initially earth ·; Cooling water provided that the cooling water of the refined water-cooled blast furnace blow mold according to between the narrow wall of the blow mold and the 60 of the French patent 792 759 goes out. Cooling water distribution body formed annulus despite the different construction described above. However, it is disadvantageous that the cooling measures. such as the special leadership of the water distribution body from a heat cooling water and the arrangement of grooves, grooves poorly conductive material, z. B. Kunstpreßstoff, 'or channels in the wall of the annulus, should be made, which one hopes to achieve, 65 is only a substantially over the entire length of the blow mold that the cooling effect distributed in the cooling water distribution body reaches, introduced cooling water whenever possible during this so that here, too, the blow mold tip is not heated by an overpass. The cooling water heating is at risk.

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In contrast to this, the invention has the object. The drawing is an exemplary embodiment

based on creating a blast furnace blow mold, the invention shown in the scheme, namely shows

which in comparison to the known blow molds Fig. 1 shows a longitudinal section through a water

a much better cooling in the most endangered cooled blast furnace blow mold,

Area, namely the blow mold tip, guarantees a top view of the blow mold according to FIG

perform. "Fig. 1,

According to the invention, the set object is achieved. FIG. 3 shows a longitudinal section through a detail

solved by that the displacement body than that of Fig. 1 on an enlarged scale:

Cooling water flowed through hollow body formed. F i g. 4 a detail of the blow molding tip in something

is that the between the displacement body and the io modified design on an enlarged scale

Blasfomiwand formed annulus only in the immediate and -,

Fig. 5 is a cross-section for this according to the section and that also only in the immediate area line V-V in FIG. 4th

the blow mold tip on the inside of the blow mold - The blast furnace blower shown in the drawing

wall the grooves, grooves or channels arranged 15 form results in a clearly defined flow of the

are. In this way, there is the advantage that the cooling water with the predictable desired

a defined speed is achieved in the area of the blow mold tip. The cold spots that a

are exposed to eddy-free flow with a relatively large high heat load, namely the

Flow rate of cooling water received, blow molding tip, can be calculated in advance

furthermore, precisely in the area of the blow mold tip, a 20 way to be cooled in such a way that the

large heat exchange surface is available, while permissible wall temperature is avoided with certainty

the currents and pressure losses in the rest are.

Areas of the blow mold are slightly lulled and. The furnace blow mold according to FIGS. 1 to 3 Finally, the displacement body for cooling is designed as a hollow body 1, so that a ring is used will. You come in this way with a 25-shaped cavity inside the wall of the an extremely small blow mold flowing through it. The blow mold is on Cooling water quantity, so that the natural circulation of the known support device 2 is attached. on Cooling water with evaporative cooling largely on the inside, an essentially cyliiia is sufficient, so that even in the case of an additional thrust or conical jacket 11 is applied a pump in extreme stress 30 den. Inside the .Hohlraumes there is a displacer the energy consumption for such a pump. body 5 used, which is dimensioned so that is very low. The favorable natural circulation explains between it and the wall of the blow mold by the fact that an annular space 9 is present as a result of the special on all sides Design of the blow mold, as I said, with a slight softening of the cooling water as described below Cooling water circulating amount is sufficient, with the 35 being able to flow through it. The displacer will A large amount of water is applied to the blow mold tip by means of spacer pins 8 at a point at a distance warming and thus high buoyancy occurs. In- held by the jacket of the blow mold 1. As a result the large buoyancy forces can be small special the Fig., 1 and 3 show, the ver-flow cross-sections at the blow mold tip, the pusher body on the jacket 1 of the blow mold is particularly endangered. 4 ° an annular resilient band 7 on. In the

An advantageous embodiment of the invention displacement body, which is also achieved as a hollow body in that the supply line for the _r . _; is formed, a cooling water supply line 3 protrudes

Cooling water into the cavity of the displacer. This supply line 3, which is designed as a tube, can

opens and that the displacement body near its one circular or preferably also one

obtained from the end remote from the blow molding tip an oval cross-section. At the passage

has circumferential gap, which is after the point of the supply line 3 in the displacement body 5

the blow mold adjacent to the wind tunnel opens. a resilient band 6 is provided, which does not

In this way one needs to be absolutely tight with simple means.

Uniform distribution of the supplied cooling water In the area of the resilient band 7, the 5 ° displacement body after the blow mold adjacent to the wind tunnel has an annular gap 5 a

wall, seen over the circumference, guaranteed. (Fig. 3), which for the passage of the cooling

The flow conditions in this pre-explanation water from the inside of the displacer into the

The distribution of the cooling water can still be there. unrestricted annulus 9 a * between the displacement

is be improved so that a bead "· body 5 and the blow mold 1 is used at the nip. 'are provided. _ 55 to the gap 5, α is the displacement with

The manufacturing effort for the blow mold and a bead 10 provided. At the connector end

their assembly is thereby significantly simplified, the blow mold wall 1 is between this blow molding

that the cooling water supply ah the entry point form wall and the displacement body 5 a

formed in the displacement body by a resilient band widened annular space 12, on which is surrounded and that the displacement body is connected to a discharge line 4 or an outlet pipe by means of ... 6 °

a resilient band on the blow mold wall is. . '::', ■ · ■ '.. ■'. ·

and is kept at a distance by pins. In the immediate area of the blow mold tip is

Finally, the flow conditions of the corresponding part 9 b of the annular space 9 can be improved by means of the fact that between the design of the displacement body 5 and the blow mold wall 1 facing away from the blow mold tip, the end of the displacement body and the blow mold wall is conical towards the blow mold tip young trained. To increase the heat, a widened annular space is formed, on which transition surface are according to FIGS. 4 and 5 into which the cooling water drain is connected. inner wall surface of the blow mold 1, namely flat

if incorporated in the immediate area of the blow mold tip, grooves 1 α or grooves or channels.

The mode of operation of the blast furnace blow mold described above is essentially the following. The cooling water passes through the Külilwasse ^ line 3 in the interior of the hollow displacement body 5 in the direction the arrows shown, (Fig. 1). Out the inside of the displacer, the cooling water passes through the gap 5 α in the direction of arrows drawn in the annular space 9, flows through first the unconstricted annular space part 9 α and then after the blow molding tip conically tapered annular space part 9 6 in the indicated arrow direction, the bead. 10 to a better The cooling water flow is deflected and the edge of the displacement body is strengthened at the same time brings about. The cooling water passes from the annulus into the widespread annulus 12 from where there is the blow mold through the outlet tube 4 leaves. As is particularly clear from FIG. 4, there is a high flow velocity of the cooling water is concentrated on the tip of the blow mold.

Claims (5)

Claims: 25 1. Water-cooled, the end of the wind tunnel forming blast furnace blow mold, which is designed as a hollow body with an annular cavity, Vin this cavity is arranged a close to the blow mold tip reaching cooling water displacer, further at the end of the blow mold remote from the blow mold tip and a Discharge for the cooling water are provided so that the cooling water the space formed between the displacement body and the blow mold wall adjacent to the wind tunnel and then after deflection in the area of the blow mold tip the space formed between the displacement body and the outer blow mold wall. flows through and wherein the wall of the annular space between the displacement body and the blow mold wall is provided with grooves, grooves or channels, characterized in that the displacement body (5) is designed as a hollow body through which the cooling, water flows, that between the displacement body and the blow mold wall ( 1) formed annular space (9 b) is conically tapered only in the immediate area of the blow mold tip and that the grooves (1 a), grooves or channels are also only arranged in the immediate area of the blow mold tip on the inside of the blow mold wall. 2. Blast furnace blow mold according to claim 1, characterized in that the supply line (3) for the cooling water opens into the cavity .- of the displacement body (5) and that the displacement body near its end remote from the blow molding tip has a circumferential gap (5 a) which opens after the blow mold wall adjacent to the wind tunnel. 3. Blast furnace blow mold according to claim 2, characterized in that a bead (10) is provided at the gap (5 a). 4. Blast furnace blow mold according to claim 2 or 3, characterized in that the cooling water supply line (3) at the point of entry into the displacement body (5) by a resilient band (6) is surrounded and that the displacement body (5) by means of a resilient band (7) on the blow mold wall (1) and is held at a distance by pins (8). . 5. Blast furnace blow mold according to one of the preceding claims, characterized in that that between the .. lying front end of the displacement body (5) and the blow mold wall a widespread Annular space (12) is formed, to which the cooling water discharge line (4) is connected. 1 sheet of drawings