EP0029081A1 - Cooling element for a metallurgical furnace - Google Patents

Abstract

A cooling element for a metallurgical furnace in which a body of cast material has cooling tubes and adapted to face the interior or the furnace and is transversely spaced opposite marginal portions. The marginal portions of the cooling element are provided with alternating tooth-like configuration having teeth and tooth gaps between them. The cooling tubes or pipes have two inlet planes and two outlet planes. The inlet ends of the cooling pipes are alternately located in one inlet plane and in the other inlet plane and are alternately located in the one outlet plane and the second outlet plane.

Description

The invention relates to a cooling element for a metallurgical furnace, in particular a blast furnace, with pipes made of steel poured into a duss body and carrying coolant and a refractory lining which is anchored in the inside face of the cooling element in recesses running parallel to the broad side of the cooling element, and the wall a metallurgical furnace formed from such cooling elements.

It is known to install cooling elements of different designs in the walls of metallurgical furnaces in order to protect the walls of the furnace. In recent years, especially for blast furnaces, an embodiment has become increasingly popular which is known as a plate cooler or "stave cooler". Such a plate cooler or cooling element consists of a cast iron body in which steel pipes are arranged, through which the coolant flows, which usually consists of water, water vapor or a water vapor-water constriction. On the side facing the inside of the furnace, the cast body has recesses into which refractory material is inserted, for example, by being taped or cast into the cast body, cf. DE-GM 7 331 936, DE-PS 1 925 478.

The individual cooling tubes of a cooling element are connected to one another in a known manner with the cooling tubes of adjacent cooling elements in such a way that the tube inlet connection piece of a cooling element and the tube outlet connection piece of the adjacent element are guided through the furnace wall or the furnace shell to the outside and are connected to one another there within a pipe bend. Due to this previously considered necessary merging of the cooling pipes outside the furnace and the butt-jointed edges of adjacent cooling elements, uncooled areas lying directly next to each other in one plane arise, i.e. Areas where heat dissipation is difficult. The result of this poor or difficult heat dissipation is destruction of the cast body in the region of the joints, in particular the horizontal joints of adjacent cooling elements. Depending on the extent of the damage, repairs are necessary, some of which can only be carried out when the furnace is at a standstill.

The invention has for its object to provide a cooling element and a wall for a metallurgical furnace of the type mentioned above, by which the disadvantages of the known cooling elements are avoided and by which, in particular, the heat dissipation in the region of abutting cooling elements is improved and thus a Destruction of the cooling elements should be prevented with extensive repairs in these areas

This object is achieved according to the invention in such a way that opposite edges or sides of the cooling element have a tooth-shaped configuration with tooth tips and tooth gaps, two entry and two exit planes being provided for the cooling tubes. Preferably, two cooling tubes each start with their respective inlet ends in one inlet level and end with their outlet levels in one outlet level, the inlet ends of the cooling tubes advantageously begin alternately in one inlet level and in the second inlet level and end alternately in one outlet level and the second outlet level. In this case, the second inlet level is assigned to the first inlet level and the first outlet level is assigned to the second inlet level.

In particular, an entry level in the area of the tooth gaps on one side of the cooling element is advantageously assigned an exit level in the area of the tooth tips on the opposite side of the cooling element and a further entry level in the area of the tooth tips is assigned an exit level in the area of the tooth spaces on the opposite side of the cooling element. In general, tooth tips and tooth gaps are preferably arranged in the transverse edges of the cooling element. According to the invention, the wall of a metallurgical furnace, preferably a blast furnace, is constructed from the cooling elements in such a way that three levels of inlet ends and outlet ends of the cooling tubes have been formed by the inlet planes and the outlet planes of two interlocking cooling elements.

In the case of assembled cooling elements, a common middle plane is expediently formed due to the interlocking or intermeshing through an inlet plane of a cooling element and through an outlet plane and through an outlet plane of the adjacent cooling element. In addition, the inlet ends and outlet ends of the cooling tubes of adjacent cooling elements outside the furnace wall are expediently connected to one another by pipe bends.

The advantages of the cooling element according to the invention can be seen in particular in that the heat dissipation in the region of abutting cooling elements in the furnace wall of a metallurgical furnace is significantly improved and accelerated, so that destruction of the cooling elements in these regions of a furnace wall is prevented. As a result, the furnace walls have a longer shelf life, resulting in less furnace downtime and lower repair costs.

The cooling element according to the invention is explained in more detail below with the aid of a preferred exemplary embodiment.

• Fig. 1 ein einzelnes Kühlelement in Vorderansicht,
• Fig. 2 eine Seitenansicht in Pfeilrichtung II in Fig. 1
• Fig. 3 einen Schnitt nach der Linie III - III in Fig. 1
• Fig. 4 einen Schnitt nach der Linie IV - IV in Fig. 1
• Fig. 5 einen Ausschnitt aus einer aus Kühlelementen gebildeten Hochofenwand und
• Fig. 6 einen Schnitt nach der Linie VI - VI in Fig. 5.

Show it:

• 1 is a single cooling element in front view,
• 2 shows a side view in the direction of arrow II in FIG. 1
• 3 shows a section along the line III-III in FIG. 1
• 4 shows a section along the line IV-IV in FIG. 1
• Fig. 5 shows a section of a blast furnace wall formed from cooling elements and
• 6 shows a section along the line VI - VI in FIG. 5.

1-4, there is a cooling element 1 for cooling the furnace wall of a metallurgical furnace, e.g. of a blast furnace, from a cast body 2, in which, e.g. four cooling pipes 3, 4 are embedded or cast. The ends of the cooling tubes 3, 4 are led out of the cast body 2 on the broad side, cf. Fig. 2 to 4, the usual way in the lower ends of the cooling tubes, the cooling medium and exits from the upper.

As further shown in FIGS. 1 to 4, the mutually opposite transverse edges 5 of the cooling element 1 are tooth-shaped, wherein each tooth head 6 of a transverse edge 5a has a tooth gap 7 in the transverse edge 5b. According to this interlocking of the transverse edges 5, the cooling tubes 3 begin in the region of the transverse edge 5b in the region of one tooth gap 7 and end in the region of the transverse edge 5a in the region of the corresponding opposite tooth head 6. The cooling tubes 4, on the other hand, begin in the region of the transverse edge 5b in the region of one Tooth tip it 6 and end in the area a tooth gap 7 of the transverse edge 5a, there are thus arranged in a transverse edge 5 of a cooling element 1, in the example shown with four cooling tubes, two cooling tubes 3 and two cooling tubes 4 each with their respective inlet ends in one plane, identified by E1 and E2 .

In the same way as the inlet ends of the cooling pipes 3, 4, their outlet ends are each arranged in an outlet plane, characterized by A1 and A2, the inlet ends E1 being assigned to the outlet plane A2 with the inlet ends of the cooling pipes 3. In a corresponding manner, the inlet plane E2 with the inlet ends of the cooling pipes 4 is assigned to the outlet plane A1.

In the recesses 8, which run parallel to the broad side of the cooling element 1, cf. Fig. 2-4, the refractory lining for the inside of the furnace is anchored.

5 and 6 show a detail from a preferred embodiment of a furnace wall of a metallurgical furnace, namely a blast furnace, which is assembled from cooling elements 1 according to FIGS. 1-4. In particular, FIG. 5 shows that through the outlet planes A1, A2 and the inlet planes E1 and E2 of two, with the transverse edges 5 adjacent or abutting cooling elements 1 three planes with inlet and outlet ends of the cooling tubes 3, 4 are formed. These are the outlet level A1 with the pipe outlets "a" of the one cooling element 1 and the inlet bone E1 with the tube inlets "b" of the adjacent cooling element 1 has a common middle level G. This level G is formed by the alternately nobon tube outlets "c" of the outlet level A2, which alternate with the tube inlets "d" of the inlet level E2 one Adjacent cooling element 1. In this case, a pipe outlet, for example the outlet plane A1, is not directly connected to one another via a pipe bend 9 with a pipe inlet of the inlet plane E1 or the plane G, but rather the pipe outlet in a tooth head 6 with the pipe inlet in the tooth gap 7 of the pipe adjacent cooling element 1 interconnected. In the same orphan, for example, a pipe outlet "a" in the area of a tooth gap 7 is connected to the pipe inlet "d" in the tooth head of the adjacent cooling element 1 via pipe elbow 9. Thus, the outlet and inlet ends of the cooling pipes 3 of adjacent cooling elements 1 and in the same way, the outlet and the inlet ends of the cooling pipes 4 of the adjacent cooling elements 1 are connected to one another via pipe bends 8 guided through the furnace shell 10.

Claims (10)

1. Cooling element for a metallurgical furnace, in particular blast furnace, with cast in a cast body, coolant pipes made of steel and a refractory lining that is anchored in the furnace-side end face of the cooling element in recesses running parallel to the broad side of the cooling element, characterized in that each other Opposing edges (5) or sides of the cooling element (1) have a tooth-shaped design with tooth tips (6) and tooth gaps (7), two entry (E1, E2) and two exit planes for the cooling tubes (3, 4) ( A1, A2) are provided. 2. Cooling element according to claim 1, characterized in that two cooling tubes (3) and two cooling tubes (4) begin with their respective inlet ends in an inlet level (E1, E2) and with their outlet ends in an exit level (A1, A2) end up. 3. Cooling element according to claims 1 and 2, characterized in that the inlet ends of the cooling tubes (3, 4) alternately in the inlet plane (E1) and in the inlet plane (E2) begin and alternately in the outlet plane (A2) and the outlet plane ( A1) end. 4. Cooling element according to claims 1 to 3, characterized in that the inlet plane (E1) is assigned to the outlet plane (A2) and the inlet plane (E2) to the outlet plane (A1). 5. Cooling element according to claims 1 to 4, characterized in that an entry plane (E1) in the region of the tooth gaps (7) one side of the cooling element (1) has an exit plane (A2) in the region of the tooth tips (6) of the opposite side of the cooling element (1) and a further entry level (E2) in the area of the tooth tips (6) is assigned an exit level (A1) in the area of the tooth spaces (7) on the opposite side of the cooling element (1). 6. Cooling element according to claims 1 to 5, characterized in that tooth heads (6) and tooth gaps (7) in the transverse edges (5) of the cooling element (1) are arranged. 7. Wall of a metallurgical furnace, in particular a blast furnace, composed of cooling elements according to claims 1 to 6, characterized in that through the inlet levels (E1, E2) and the outlet levels (A1, A2) of two interlocking cooling elements (1) three Levels of inlet ends and outlet ends of the cooling tubes (3 and 4) are formed. 8. Wall of a metallurgical furnace according to claim 7, characterized in that a common middle plane (G) is formed, through the inlet plane (E2) of a cooling element (1) and through the outlet plane (A2) of the adjacent cooling element (1). 9. Wall of a metallurgical furnace according to claims 7 and 8, characterized in that in each case the inlet ends and outlet ends of the cooling pipes (3) and the inlet ends and outlet ends of the cooling pipes (4) of adjacent cooling elements (1) outside the furnace wall by pipe bends (9) are interconnected. 1 ₀ . Wall of a metallurgical furnace according to claims 7 to 9, characterized in that in each case a pipe outlet (c) in a tooth head (6) of a cooling element (1) with a pipe inlet (b) in the tooth gap (7) and a pipe outlet (a ) in the tooth gap (7) of a cooling element (1) with a pipe inlet (d) in a tooth head (6) of the adjacent cooling element (1).
Reference numbers 1 cooling element 2 cast bodies 3rd
4 cooling pipe 5 cross border 6 tooth head 7 tooth gap 8 recesses 9 elbows 1o furnace shell E1, E2 inlet levels A1, A2 exhaust levels G common middle level from E2 and A2 a Pipe outlets in outlet level A1 b Pipe inlets in inlet level E1 c pipe outlets in A2 (G) d pipe inlets in E2 (G)

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