DE2446926C2 - Suspended gas heat exchanger - Google Patents

Description

The invention relates to a suspended gas heat exchanger, Containing at least one cyclone stage consisting of at least two external cyclones and at least one central flow space. into which the (iutaustragsleitungcn of the two cyclones with adjustable, tube-like linden trees open.

Suspended gas heat exchangers of the type mentioned would be used for various heat treatments as well as / λ, ■ '· part also / to cool down goods. in particular fine material, is used, it being possible for the material to be treated and the treatment gases to be conducted in countercurrent and / or cocurrent to one another, the desired heat exchange then taking place between the material and the gas

However, it has been shown in practice that at Suspended gas heat exchangers of the type mentioned in the outer cyclones of the cyclone stage or cyclone stages a different treatment occurs This is extremely unfavorable especially in those cases in which the Suspended gas heat exchanger is used, for example, as a preheating device for cement raw meal, which is then to be treated in an oven (ζ. Β. rotary kiln). In this case, the different treatment in the outer cyclones of the cyclone stage in an uneven deacidification of the cement raw meal noticeable, which is extremely undesirable

From GB-PS 12 14 375 a suspension gas heat exchanger is now already known in the permanently installed crop discharge lines of the cyclones adjustment flaps or control elements / ur regulation of the Material flows are provided. Such an adjustment option for that in the central flow space good to be registered has proven to be completely inadequate.

From US-PS 32 65 775 can also be a suspension gas heat exchanger in the one embodiment Refer to the type mentioned at the beginning. In this case the material discharge lines are from two outer ones Cyclones are rigidly connected to the central flow space, while the material discharge lines have two further cyclones can be adjusted in their axial length so that they are at different altitudes in can open into the central flow space. However, it has been found in practice that even with such adjustability of the confluence ends of the cyclone discharge lines, none noticeably more even treatment of fine material in the outer cyclone stages of a S "hwebegas heat exchanger can achieve

The invention is therefore based on the object while avoiding the disadvantages of the known To create embodiments of a floating gas heat exchanger of the type mentioned, in which with relatively simple structural means, at least a particularly even division of the in the central flow space brought in on the connected to this part of the flow space outer cyclones is achieved.

This object is achieved according to the invention in that the confluence ends of the material discharge lines S'nd arranged to be pivotable relative to the stationary central flow space.

As has been shown on the basis of numerous experiments on which the invention is based, the Disadvantages of the known floating gas heat exchangers due in large part to the fact that the outer cyclones of a cyclone stage are charged with different amounts of material. Through the inventive design of the confluence ends in the material discharge lines of the outer cyclones, d. H. in particular due to their pivoting adjustable arrangement, is now with simple constructive Funds created the possibility of these opening ends to be adjusted in each case so that the falling f iut so in the stationary central flow space and somii the Hchandluncseasstmm ascending therein

arrives that the 8;. · this section of the central External cyclones connected to the flow space can be acted upon particularly evenly. It has also been shown that not only a more even distribution, but also an extremely favorable distribution of the ascending gas flow to the corresponding outer cyclones can be achieved can.

As has already been mentioned above, can use this floating gas heat exchanger for very different heat treatments. Especially good This suspension gas heat exchanger is suitable in one embodiment as a preheating device for in one downstream furnace to be treated, with the exhaust pipe of the furnace down to the central Flow space is connected, so that the furnace exhaust gases are used to preheat the goods. In addition, several cyclone stages are provided one above the other, the cyclones of which are uniform in each case are arranged distributed around the central flow space; in addition, the central Flow space at least one shaft-like central vortex space and one at the lower end of this Vortex space connected upper exhaust pipe and one with the lower end of this vortex space a lower gas pipe connected to the pipeline. Then open in a particularly advantageous manner at least the bottom discharge lines. Cyclone stage by means of the pivoting confluence ends into the lower section of the central flow space formed by the lower gas pipe. This allows raw cement in particular to be added to a furnace downstream of the preheating device is to be treated, must be deacidified very evenly in all outer cyclones of the lowest cyclone stage.

Of course, the confluence ends of the cyclone material discharge lines of the upper Cyclone stages be adjustable in the manner described. The following is an embodiment of the invention explained in more detail with reference to the drawing. It shows

Fig. 1 is a schematic overall view of a floating gas heat exchanger which is used as a preheating device designed for cement raw meal and upstream of a rotary kiln;

2 shows a partially sectioned view of a The point where a product discharge line flows into the central flow space (according to section II in Fig.l).

The floating gas heat exchanger illustrated in FIG. 1 is used as a preheating device 1 for example for raw cement meal to be preheated (material to be treated) executed, which is then in one of the preheating device downstream rotary kiln 2 in the desired Way to be treated.

The illustrated preheating device 1 contains a bottom cyclone stage 4 consisting of at least two outer cyclones 3, 3 ', a middle cyclone stage 6 consisting of the outer cyclones 5, 5' and an upper cyclone stage 8 consisting of the outer cyclones 7, τ, the cyclone stage 4, 6 and 8 are provided in tiers one above the other and the outer cyclones of these cyclone stages are each arranged essentially evenly distributed around a central flow space 9 of this preheating device I. The central flow space 9 comprises at least one layer-like central vortex space 50. one at the top; Straight upper exhaust pipe 11 connected to the end of this vortex space 10 and a lower gas pipe 13 connected to the lower end of this vortex space 10 via a material line 12. As can also be clearly seen from FIG. 1, the lower gas pipe 13 branches off to the: Cyclones 3, 3 'of the lowest cyclone stage 4, while the upper exhaust pipe 11 branches off to the cyclones 5, 5' of the middle cyclone stage; the cyclones 5, 5 'are connected in the usual way via their exhaust pipes 14, 14' to the cyclones 7, T of the uppermost cyclone stage 8, while the exhaust pipes of the uppermost cyclones 7, T merge into a common line 15 which leads to a fan 16 leads.

At the bottom of the central flow space 9, more precisely at its through the lower gas pipe 13 formed lower portion, the exhaust pipe 17 of the rotary kiln 2 is connected so that the Furnace exhaust gases (dashed arrows 18) through the preheater 1 essentially from bottom to top central flow space 9 and the connected cyclone stages 4,6,8 can flow through.

The discharge lines of the outer cyclones flow into the central flow space 9 at different heights, namely the discharge lines 19, 19 'of the cyclones 3, 3' (lowest cyclone stage 4), into gas inlets 46, 46 'of the lower gas pipe 13 Vortex chamber 10, the Gutaustragslinien 20, 20 'of the bottom cyclones 5,5' (middle cyclone stage) and approximately in the middle part of the upper exhaust pipe 11, the Gutaustragslinien 21,2Γ of the outer cyclones 7, 7 '(top cyclone stage). The task of the raw meal (solid arrows 22) takes place via a material line 23, which branches off to the exhaust lines 14, 14 'so that the freshly fed raw meal first enters the cyclones 7, T of the top cyclone stage and then gradually the Cyclone stages 8, 6 and 4 or the central flow space 9 traversed from top to bottom opposite to the direction of the rising furnace exhaust gases.

The confluence ends of the material discharge lines from the outer cyclones are designed to be adjustable at least in the case of the material discharge lines 19, 19 'from the lowermost cyclones 3, 3' into the lower gas pipe 13; however, the confluence ends of the material discharge lines 21, 2Γ of the uppermost cyclones 7, T in the upper exhaust line 11 can also be designed to be adjustable. The structural design of the end of the confluence of a material discharge line can be seen from FIG. See 2 in more detail; this constructive training is for the different material discharge lines

" ^{] 0} gen essentially identical and of course adapted to the corresponding arrangement.

In Fig. 2, the junction end 30 of the material discharge line 19 shown in more detail as an example of the lowest cyclone 3.

"As can be seen from FIG. 2, the material discharge line is 19 and, in the same way, their confluence end 30 is tubular, η this Trap with a round or circular cross-section. The junction end 30 is with the remaining part 31 of the Gutaustragsleitung 19 verbuncen with a releasable adjusting flange 32. On the wall 33 of the lower Gas pipe (from the central flow space 9) a mounting bracket 34 is attached (z. B. welded) on the free end of which the associated junction end 30 "'is supported so as to be pivotable 30 tangles completely or is only encompassed in a fork-like manner by the free end 35. At the console 34 are at least two Drucklageisdiraubcn 36 provided.

which on the part 35 of the console 34 comprising the junction end 30 are diametrically opposite to the junction end 30 (in FIG. 1 only one thrust bearing screw 36 of two screws can be seen). A bearing block 37 is supported on each of the ends of these adjustable thrust bearing screws 36. which is attached to the mouth end 30 on the corresponding outside. In addition or alternatively to this pivot bearing ring (36, 37), such bearings can be angularly replaced on the console 34 or at the "junction end 30. In this way, the junction end 30 can be opposite the stationary lower gas pipe 13 of the central flow space 9 In order to be able to carry out this pivoting and thus an adjustment of the junction end 30 with respect to the stationary gas pipe 13, the adjustment flange 32 is released beforehand; after the adjustment has been carried out in the desired manner, the junction end 30 is moved over the adjustment flange 32 again (in the new position) x ' established.

An additional adjustment of the confluence end 30 can also be achieved by holding this confluence end 30 on the mounting bracket 34 so that it is adjustable in the direction of the gas pipe 13 and in the direction of 2ί of this gas pipe, so that the distance between the confluence end 30 indicated by the double arrow 38 and the wall 33 of the gas pipe 13 can be adjusted.

In the wall 33 of the lower gas pipe 13 (from the Jo flow space 9) a pipe piece 39 is inserted, which is directed obliquely upwards and outwards and the lower end of the associated junction 30 coming from above encloses at a distance so that it is between the outer wall of the junction end 30 and the inner wall of the pipe section 39 results in a gap 40. While this intermediate space 40 also opens freely into the lower exhaust pipe 13 at its lower end, it is closed at its upper end by a seal 41. This ring-shaped ^4fl ge seal is mounted at the upper end of the Rohrstiickcs permanently attached 39 and formed in a urine I »ι gland 41st

In the upper end of the annular intermediate space 40, a blow line 42 opens. which can preferably be a compressed air inlet which can be connected to an existing compressed air inlet via a valve 421. The blow line 42 preferably surrounds the stirring piece 39 in a ring shape and ends with several branch pieces 42b at an angle in the intermediate space 40 such that this intermediate space 40 can be blown free in the direction of the central flow space if necessary. By this friblowing, the pivoting of the opening end 30 can be secured in an advantageous manner, since any good particles deposited in the space 40 are removed in this way and cannot hinder the pivoting of the opening end piece 30 in any way.

Below each confluence point, which is passed through the mouth openings 44 of the confluence ends 30 a cyclone stage is defined in the central flow space 9, there is an impact distributor 45 or 45 '(see also Fig. 1), which is permanently installed in the central flow space and preferably through a bridge is formed which traverses this flow space in a known manner; however, it can also another organ designed in a suitable shape can be provided, by means of which this is ensured. that of a supply line (e.g. 19) coming, proportionately compact raw meal flow is evenly dissolved in order to achieve a good heat transfer. For an exact division of both the rising gas flow on the one hand and the downward flowing gas flow On the other hand, the flow of raw meal becomes the confluence end 30 opposite the stationary central flow space and in particular adjusted with respect to the mentioned impact distribution element 45 or 45 '. at Tests have shown that it is useful to have an impact distribution element designed as a bridge opposite conventional embodiments to make a little wider.

In addition 2 Biatt drawings

Claims (8)

Patent claims: 1. Suspended gas heat exchanger containing at least one of at least two outer cyclones existing cyclone stage and at least one central flow space into which the material discharge lines of the two cyclones open out with adjustable, tube-like ends, characterized in that the confluence ends (30) of the crop discharge lines (z. B. 19) jo are arranged such that they can pivot relative to the stationary central flow space (9). 2. suspension gas heat exchanger according to claim 1, characterized in that at the central flow space (9) for each confluence end (30) the Gutaustragslinien (z. B. 19) a bracket (34) is attached to which the associated Confluence end is pivotally supported, and that each confluence end (30) with the remaining part (31) of the Gutaustragsleitung (19) over a releasable adjustment flange (32) is connected. 3. suspension gas heat exchanger according to claim 2, characterized in that each confluence end (30) of the Gutaustragslinien (z. B. 19) on its console (34) also in the direction of and to central flow space (9) is adjustable. 4. suspension gas heat exchanger according to claim 2, characterized in that the pivotable Holder of the confluence ends (30) of the material discharge lines (e.g. 19) on the consoles (34) Pressure position screws (36) are provided which bearing blocks p7) attached to the confluence ends (30) are supported. 5. suspension gas heat exchanger according to at least one of the preceding .nsprüche, thereby characterized in that in the wall (33) of the central flow space (9 or 13) for each material discharge line (z. B. 19) an outwardly protruding pipe piece (39) is attached, which the lower end of the associated confluence ends (30) to form an intermediate space (40). 6. suspension gas heat exchanger according to claim 5, characterized in that the upper end of the firmly inserted pipe section (39) has a seal (41), which the outer wall of the associated The confluence end (30) encloses. 7. suspension gas heat exchanger according to claim 6, characterized in that a seal Stuffing box (41) is provided. 8. suspension gas heat exchanger according to claim 5, characterized in that in the annular Gap (40) between the pipe section (39) and the associated confluence end (30) a Blow line (42) opens.