FI82308C - L-shaped lifting bucket for pipe coolers - Google Patents

Abstract

1. L-shaped lifting blade for tubular coolers, in particular such as are used for crushing and cooling cement clinker, of which one side forms a fastening section provided with at least one screw opening, and the other side forms a carrier section with a receiving trough bounded by a curved bottom wall, characterised in that the two end areas of the receiving trough (7) of the side forming the carrier section (5) lie on a reference plane (B) which forms an angle a of 93 degrees to 105 degrees with the other side (fastening section (1)), in that the receiving trough (7) is 2.5 to 5 cm deep at its longitudinal centre as measured from the reference plane (B) and has its deepest point here, and that the length of the carrier section (5) measured normal to the fastening section (1) is 16 to 24 cm.

Description

1 82308 L-shaped lifting wing for pipe cooler

The invention relates to an L-shaped lifting vane for a pipe cooler, in particular for pipe coolers for grinding and cooling cement clinkers, in which one branch forms a fastening part with at least one screw hole and the other branch a gripping part with a receiving chute delimited by a curved bottom wall.

10 Such lifting vanes are attached to the casing of the condenser immediately or by means of clamps.

Such lifting vanes have long been used in radiators rotating about a slightly inclined axis relative to the horizontal, e.g. in satellite chillers in the cement industry. Their function is to contribute to the improvement of heat transfer from the material to be cooled to the cooling air flow, as they raise the entrained hot material during slow circulation and allow it to flow in a denser or less frequent mesh through an air-jet over the entire diameter of the radiator.

In order to achieve the most uniform cooling possible, the aim has hitherto been to make the material to be cooled as uniform as possible with a curtain of the entire cross-section of the radiator. This has the disadvantage that, according to the flow of cooling air, fine-grained particles of the material to be cooled are entrained.

The cooling air introduced upstream of the material to be cooled preferably flows through the path with the lowest resistance. If the curtain of material to be cooled did not completely cover the cross-section of the radiator, the cooling air would thus flow mainly through the areas free of materials to be cooled. It would then correspondingly lose its cooling effect, and the efficiency of the cooler would decrease. Therefore, the known lifting vanes are shaped like a bucket 35 so that, as the radiator rotates, the material to be cooled is delivered more or less evenly in successive angular positions during the rotation of the radiator.

2 82308 The essential disadvantage of these known bucket-shaped lifting vanes is their relatively short service life. In addition to their thermal and chemical loads, these lifting wings are also very mechanically stressed. With each rotation of the radiator 5, the lifting vanes become strongly heated during the bucketing operation, i.e. upon receipt of the material to be cooled, and then cool in the cooling air flow. In this case, the temperature difference between the wings can be as high as 500 ° C. Since the material to be cooled also usually has larger or smaller boulders, which are also lifted and thrown away, the front ends of the wings break very quickly and roll inwards.

These vanes can no longer properly perform their intended function in the radiator.

The object of the invention is now to provide a lifting wing of the quality mentioned in the introduction, which does not have the said drawbacks and which is characterized by a long service life in connection with a good cooling effect.

This object is solved in connection with a lifting wing according to the invention of the quality 20 mentioned in the introduction, so that both end regions of the receiving trough of the branch forming the gripping part are located in a reference plane forming an angle "X" of 93 ° to 105 ° with the other branch (fastening part), the receiving trough is 2.5-5 cm deep in the middle of its length, measured from the reference plane, and has the deepest point here, and that the length of the fastening part of the gripping part, measured normally, is 16-24 cm.

In connection with this lifting vane, a relatively early ejection of the cellular material to be cooled is achieved only in the cross-sectional area of the condenser. This results in the lifting vane being subjected to the cooling effect of the cooling air over a longer distance when the radiator is rotated. In this case, the lifting wing according to the invention is shaped in such a way that its bearing surface is large. 35 hours compared to the amount of material to be cooled. This means that there is more heat transfer between the material to be cooled and the lifting vane. Due to their shape as cooling fins 3 82308, they cool rapidly and permanently under the influence of the cooling air flow. The material volume of the lifting blade itself is then relatively small and accordingly stores less heat than hitherto known far-flung blades and also conducts this to a lesser extent in the radiator jacket.

In the use of these lifting vanes, the cross-section of the radiator is divided into a part where the material to be cooled falls down substantially in a curtain, and a second part 10 through which cooling air is introduced, the number of particles entrained by the cooling air flow is substantially reduced.

The lifting wing according to the invention is then shaped in such a way that it is located in its basic direction like a sword against the falling angle 15 of larger blocks of material falling down, whereby it provides these blocks with a negligible bouncing surface. Larger, bouncing boulders hit the front edge of the lift wing, from which the bounce energy is immediately applied to the mounting part. This greatly avoids wear and damage to the lift vane and, in addition, provides good fragmentation of the larger boulders to be cooled. When the boulders hit the sides of the lifting wings, the boulders are deflected away, so the bounce energy is reduced.

The lifting wing according to the invention can be shaped so that the angle χ is 97 ° -100 °. With a slope in a given range of 25a, particularly advantageous results can be obtained according to current experiments.

The lifting wing according to the invention can further be shaped so that the maximum depth of the receiving trough measured from the reference plane is 2.5-3 cm.

The lifting wing according to the invention can be further shaped so that the length of the gripping part is 16-18 cm.

The lifting wing according to the invention can further be shaped so that the gripping part has a reinforcing ball at its edge remote from the fastening part. In this way, additional reinforcement 35 is provided to the area of the lifting wing where the impact of the rough boulders must be taken into account.

4 82308

The lifting wing according to the invention can further be shaped so that the receiving trough is divided by at least one wall connecting its two end areas. This promotes the distribution of material over the width of the lift vane.

Finally, the lifting wing according to the invention can be shaped so that at least one stiffening rib is arranged between the bottom wall and the fastening part. This stiffening rib greatly increases the stability of the lifting wing.

In the following part of the description, one embodiment of a lifting wing according to the invention 10 will be explained in connection with the drawings. In this case: Fig. 1 shows a view of the lifting wing according to the invention in a radially inward view, Fig. 2 a top view of the lifting wing according to Fig. 1, Fig. 3 a side view of the lifting wing according to Figs. 1 and 2, Fig. 4 a section of the lifting wing according to Fig. 2 and a section of a pipe cooler comprising lifting vanes 20 according to the invention mounted along.

The lifting wing "according to the invention shown in Figures 1-5" is substantially L-shaped in its side view (Figures 3-5).

The second leg is then formed by a plate-like fastening part 1 provided with two outwardly projecting shoulders 2.

In the fastening part 1 there is a screw hole 3 in the area of each shoulder 2, into which a screw (not shown) can be inserted to fasten the lifting wing to the pipe cooler jacket 4. In a side view, the second branch of the L-shaped lifting wing is formed by a gripping part 5 with a bottom wall 6 7 is divided by two side walls 8 and a partition wall 9. The side walls 8 and the partition wall 9 extend substantially parallel to each other in one end region of the gripping part to its other end region.

! The bottom wall 6 is provided with a reinforcing flange 13 at its edge furthest from the fastening part 1.

5 82308

In addition to the bottom wall 6, the two stiffening ribs 14 located parallel to each other rest on the fastening part 1.

The edges delimiting the receiving trough 7 in the middle end areas are located in a reference plane B, which forms an angle of 95 ° -100 ° with respect to the fastening part 1 5. The maximum depth of the receiving trough 7, measured from the reference level B, is 2.5-3.0 cm. The length L of the gripping part 5, measured normally, of the fastening part is 16-18 cm. This described length L decreases in connection with the described lifting vane towards its sides, because the reinforcing ball 13 is slightly bent backwards at its ends.

Claims (7)

1. L-shaped lift shovel for pipe coolers, in particular for pipe coolers intended for disintegration and cooling of cement clinkers, in which one shovel forms a fastening section provided with at least one screw heel and the other shank a bracket cut-off, such as a rake cut, which is limited by an arched bottom wall, characterized in that both end regions of the receiving portion (5) forming the receiving funnel (7) lie at a reference level (B), which with the attachment section (1) of the other leg forms a angle a, which is 93 ° -105 °, that the receiving funnel (7) in the middle of its length measured from the reference level (B) is 2.5-5 cm deep and that it has its deepest position and that it normally tilts the measured length (L) of the carrier section (5) of the fitting section (1) is 16-24 cm. 2. A lifting bucket according to claim 1, characterized in that the winding angle is 97 ° -100 °. 3. A lifting vane according to claim 1 or 2, characterized in that the maximum depth measured from the reference level (B) of the receiving funnel (7) is 2.5-3 cm. 4. Lifting bucket according to any of the preceding claims, characterized in that the length of the carrier section (5) is 16-18 cm. 5. A lifting vane according to any of the preceding claims, characterized in that the carrier section (5) on the facing edge away from the fastening section (1) comprises a reinforcing roller (13). Lifting vane according to any of the preceding claims, characterized in that the receiving funnel (7) is divided by at least one wall joining its two end regions. Lifting vane according to any of the preceding claims, characterized in that at least one stiffening pontoon (14) is arranged between the bottom wall (6) and the fastening section (1).