DE2225097A1 - Rotary furnace with planetary cooler - Google Patents

Description

Patent Attorney Dr. Ing.A. van der Werft ι MAY 3, 1972

Dr. Ψ, loader

SM Harnburg SO 6199-3

Street 32

FLSmidth & C ₀ . A / S.

Yigerslev All 77 »Copenhagen-Yalby / Denmark

Rotary furnace with planetary cooler

Priority: May 25, 1971, Great Britain, No. 17021/71

The invention relates to a rotary kiln, for example a cement kiln, equipped with cooler tubes which are planet-like disposed around the outlet end of the furnace and adapted to receive and means of the rotary kiln product To cool air which is caused to flow through the cooler tubes in countercurrent to the rotary kiln product, each cooler pipe being connected to the interior of the furnace by a connecting chute and an inclined wall portion which is inclined to the axis of the cooler tube opposite the opening of the chute in the cooler tube.

The inclined wall will therefore be located on the side of the cooler pipe which is remote from the furnace during the The part of the cooler pipe close to the furnace is circular retains cylindrical shape in its entirety. With this construction, the connection slide can be uneven other slides can be unusually short, and this is beneficial in many cases. This is the case, for example, when the oven-treated material tends to stick to the chute wall, mainly to the part the wall that is furthest in the direction of rotation of the furnace.

As the furnace rotates, the material will begin to fall and expand depending on its sliding behavior

the stove through the connecting bag "move about to the Time how the corresponding cooler pipe passes through its lowest position. The flow of material through the chute will then "increase to a maximum before it decreases again and finally stops completely when the slide approaches its horizontal position. During this time, a quantity of material, which extends along the lowermost generatrix the chute has accumulated during the continued rotation of the furnace, re-enter the furnace as reflux. This return is unavoidable to a certain extent, but should be limited as much as possible, because the return of material has a strong abrasive effect on the furnace lining. The shorter the slide, the smaller is the amount of return flow and the less wear and tear on the furnace lining. As for this wear and tear, it is therefore, it is desirable to make the chute as short as the formation of the inlet end of the cooler tube allows. On the other hand, this training has certain drawbacks. So it is less suitable for promoting advancement of the rotary kiln product through the cooler tube than other designs which, for example, have an adapted slide " have, which opens into an inclined ^ end wall of the cooler tube. The beneficial properties associated with the aforementioned Forming a short slide are connected, which opposite an inclined 'wall part of the cooler pipe opens up, and has a negligible tendency to stick consist in the chute and a negligible return flow into the furnace, can thus be reduced as a result of a Delivery rate will be lost.

According to the invention, this deficiency is overcome by Providing a deflector within each cooler tube to the side of the cooler tube which is adjacent to the furnace Opening the chute into the cooler tube is adjacent, the deflector being oriented so that during rotation of the cooler tube it will promote the conveyance of the rotary kiln product along the cooler tube from the point where the Slide opens into the cooler pipe.

The deflector can suitably be designed as an arch

surface
whose convex contact is with the wall of the cooler pipe, or it can be in the form of an inwardly directed projection in the pipe wall, preferably coated with a lining material. The use of an internal protrusion on the tube wall ensures effective cooling of the deflector.

The deflector can also be designed with a boundary surface which essentially represents a tangential plane to the linkage route. This will keep that to a minimum Reduce the volume of the cooler pipe from which return flow into the furnace can take place.

The edge of the deflector can, or it can, have a constant radius of curvature, which is the simplest form have a variable radius of curvature with its maximum where the edge meets the rotary kiln product, what the Can improve funding performance.

Some examples of rotary kilns according to the invention are at the Drawings explained which represent:

Pig. 1 shows a vertical longitudinal section through an end part of the furnace and through a cooler pipe,

Fig. 2 is a section along line II-II of Fig. 1,

3 shows a section corresponding to FIG. 1 of a second exemplary embodiment,

Fig. 4 is a section along line IV-IV of Fig. 3,

5 shows a section corresponding to FIG. 3 through a third exemplary embodiment, and

FIG. 6 shows a section along line VI-VI of FIG. 5.

According to FIGS. 1 and 2, a rotary kiln has a jacket 1 and is equipped with a number of cooler tubes which are planetary around the outlet end of the furnace with their axes are arranged parallel or substantially parallel to the furnace axis and are designed to receive the rotary kiln product and to cool by means of air which is caused by the

2 0 9 8 b 0/0 8 5 3

To flow cooler tubes in the blessing stream to the rotary kiln product, each cooler tube 2 is therefore in connection with the furnace interior by a connecting chute, which consists of a tube end 3 which protrudes from the furnace shell 1 and in which an inner tube 4 is held, which with a the cooler pipe 2 protrude ^ en pipe end $ is in connection. Inside the furnace, the free end of the inner tube 4 is flush with a lining, not shown, with which the furnace is provided.

Opposite the point where the connecting chute 3, 4, 5 opens into the cooler pipe 2, pipe 2 has an inclined wall 6, which can be partly cylindrical, partly conical or both, and to which a small flat end wall 7 is connected is. A deflector 8 is provided in the cooler pipe immediately after the point where the connecting chute 3, 4, 5 in the cooler pipe 2 opens. The deflector 8 is approximately in the shape of a crescent moon with a maximum height extending up to 15 to 25% of the inner diameter of the cooler tube can, and the axis of symmetry of the deflector can be shifted relative to the slide, that is relative to the line the closest approach between the cooler tube and the furnace, by an angle of 15-30 around the axis of the cooler tube in the direction of rotation as indicated by an arrow in the figure. The deflector 8 according to FIGS. 1 and 2 forms a partial spiral with a pitch between, for example, 20 and 60, and is oriented in such a way as to promote the rotary

oven product away from the mouth of the binding chute 3, 4, 5 into the cooler tube 2 during the rotation of the furnace and tube.

Figures 3 and 4 show a deflector 9, but of the form of an inwardly bulged projection in the pipe wall and covered with a lining. The projection h & τ. the shape of a channel with a symmetrical trapezoidal »cross-section with an apex angle of approximately 90 ° and is oriented in the cooler tube in a manner similar to that of the bend 8 in FIGS. The projection 9 is formed by cutting an opening in the cylindrical KüMerrohrwand and in this opening ¹ an angular approach is a US Blec limate overall rial

2098faÜ / 0853

welds. This makes a more powerful distractor than what is made by: Using an arc is obtained, and the deflector can be kept at a relatively low ^ temperature because it is cooled from the outside by the atmospheric air.

Figures 5 and 6 show a modification of the deflector of the Pig. 3 and 4. It has the shape of an inward one bulged projection which is created in the pipe wall and covered with a lining. Of the Deflector 10 has a boundary surface 11 which essentially represents a tangential plane to the inner surface of the connecting chute 3,4,5 »^ he projection is in this case as a channel of unbalanced, trapezoidal Cross-section formed with a tip angle of about 45 °

The modification of FIGS. 5 and 6 also differs from the embodiments of the preceding figures in that the Connecting chute 5 does not lead symmetrically into the cooler pipe, but rather in relation to the center line of the Cooler tube is offset, for example by so much that the tube end 5 extends tangentially into the cooler tube 2 This construction results in a correspondingly larger free: Fall from the opening of the chute into the radiator pipe The deflector 10 also does not have an edge with a curvature of constant radius, but be. Radius of curvature fluctuates in such a way as to be where at its maximum the edge meets the rotary kiln product.

209 8-5 0/0853

Claims (2)

Claims 1 “Rotary kiln with a number of planets around the outlet end of the furnace, the inlet end of each tube being connected to the furnace by a connecting chute is characterized in that each tube has an inner deflector to the side of the cooler tube which is adjacent to the furnace and the opening of the chute in the cooler tube, and so that the deflector is oriented is that during the rotation of the radiator pipe he förderun of the rotary kiln product along the cooler tube from where the chute opens into the cooler tube 2. Rotary kiln according to claim 1, characterized in that that the inner deflector of the cooler tube is an arch, the convex surface of which is in contact with the wall of the Cooler pipe is. 5. Rotary kiln according to claim 1, characterized in e t that the inner deflector of the radiator pipe is the ϊοπη an inward protrusion in the pipe wall 4. Rotary furnace according to claim 3, characterized in that that the deflector is covered with a liner 5. Rotary kiln according to one of the preceding claims, characterized in that the deflector has a boundary surface which is a tangential plane to the connecting chute between the furnace and the cooler pipe. 6. Rotary kiln according to one of claims 1 to 4 »thereby characterized that the deflector edge has a constant radius of curvature « 7. Rotary kiln according to one of claims 1 to 4, characterized in that the deflector edge one changing radius of curvature possesses - with its maxium the point where the edge meets the rotary kiln product. 2 0 9 8 b Ü / 0 8 5 3