DE2317303A1 - MANHOLE FURNACES - Google Patents

Description

PATENT LAWYERS

DiPL-ING. BUSCHHOFF

DIPL-ING. HENNiCKE BE 15 212

DIPL-ING. VOlUACH '

5 COLOGNE

KALSER-WiLHEiM-RlNG 24

Cologne, April 4, 1973 C.E .: Mr 809

MAERZ OFENBAU AG,. Zurich

(Switzerland)

Shaft furnace

The present invention relates to a shaft furnace for firing granular material, consisting of three identical, circular ones or polygonal shafts which are arranged at angles of 60 and of which one shaft at a time is heated in cocurrent with the falling material, while the flue gases of this shaft through the other two, in parallel remove switched, unheated shafts in counterflow, wherein each shaft has an annular channel in the area between the combustion zone and the cooling zone, the annular channels one below the other lie at the same level and are connected by branch channels.

309846/0777

It is a furnace system with four shafts and four channel systems known (GB-PS 4166/1902), of which the first channel system of the supply of the heating gas to one of the shafts, the second of the forwarding of the hot air from the shaft, which has cooled down becomes, to the combustion shaft, the third one for the transmission of the flue gases from the combustion shaft to the preheating shaft and the fourth serves to discharge the flue gases into the chimney. One of the four shafts is switched off and the other three for each Phase connected in series. This results in a complicated pipe connection between the shafts, which alternate between the bottom and above is done.

Also known are shaft furnaces for the heat treatment of granular Good, e.g. for burning limestone, which consist of three shafts connected to one another, one shaft in direct current is heated with the downward moving good, while the flue gases through the other two ducts in countercurrent to drain upwards to the good. The smoke gases from the heated shaft emerge from the material slope in the area between the combustion zone and cooling zone, with a circular or polygonal shaft cross-section into a ring channel, out of and through the analog ring channels of the exhaust shafts into their fill. The three ring channels are in the known design by three short, under 120 arranged, straight branch channels connected in the form of a 3-armed star. Ring channels and branch channels are on same level. This star arrangement of the branch channels. Below Angles has the advantage that the state of the smoke gases (composition, temperature, pressure, etc.) is in the center of the star, where the three branch channels meet, can be checked in a simple manner, but this advantage is available serious operational disadvantages compared to:

a) The flue gases from the ring duct of the heated shaft flow from two sides of the connection cross-section of the associated Branch channel too. There where the two currents

09846/0777

of the ring channel meet, they are at the same time deflected at right angles. Both flow processes, the meeting and the deflection, lead to violent eddies, which continue in the branch duct and lead to strong dust deposits. The deposited dust can depend on of its alkaline content and the SO_ content of the Flue gases form solid crusts which disturb the flow in the furnace and which have to be removed periodically. Another The cause of the vortex formation is the deflection of the smoke gases at the fork in the branch duct. The formation of eddies at the transition from the ring channel to the branch channel of the star arrangement has the further disadvantage that it is when the fuel is heated The shaft is not 100% burned out, during the vortex formation to an intimate and complete mixing of unburned matter comes with the combustion and cooling air. The sudden afterburning results in locally higher wall temperatures, which; lead to severe sintering of the dust deposits.

b) The cross-section of the branch channels is limited, a certain flow velocity cannot be fallen below, because the ceiling of the branch ducts should also for static reasons be at the same level :: as the ceiling of the ring ducts, and their bottom must be higher than the bottom of the annular channels formed by the material slope in order to prevent the deposition of Avoid firing material on the base of the branch duct.

c) The length of the branch channels and thus the length of the sole, on which dust crusts can attach, cannot be reduced be shortened to a minimum, because at the points where two opposite ring channels come closest to each other walls of at least 2 χ 250 mm (two normal brick lengths) can still be accommodated.

d) The ceiling over the branch ducts must be in the form of a straight line Vault are executed. Suspended ceilings come

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for out of the question, on the one hand, because of the difficulty of them to be sealed when connecting to the ring ducts (such Furnace works with excess pressure), on the other hand the supporting structure would a suspended ceiling, the arrangement of poke openings, measuring openings, etc. in the ceiling and the accessibility to make this very difficult. So it only remains that Solution to build the ceiling over the branch ducts from three straight arches in the shape of a cross. With this ceiling shape If the ceiling length is greatest in the middle and decreases towards the abutment, which is undesirable for reasons of load is. The wider the branch channels, the shorter the ceiling on the abutments. Here, too, there is a limit for the width of the branch channels.

The object of the present invention is to create a shaft furnace which does not have the disadvantages of the known design having. This object is according to the invention by a Shaft furnace of the type mentioned above solved, in which each ring channel of a shaft by one constantly open Branch channel is connected to each of the other two manholes and the position of the branch channels corresponds to the sides of a triangle. This arrangement of the branch channels ensures that two shafts are connected in parallel and therefore only about half of the amount of gas applied to the branch channels are. In addition, the branch channels are arranged where 'the shafts or the ring channels come closest, and it can be the masonry necessary for the star arrangement in the area the branch ducts between the ring ducts are partially omitted, the shafts moved closer and the branch ducts shorter are executed.

The invention is shown in the accompanying drawings in FIGS 4 shown and with the known embodiment of FIGS. 1 and 2 compared. It shows:

309848/0777

Pig. 1 A horizontal section through a shaft furnace with three shafts at the level of the ring channels with star-shaped Arrangement of the branch channels according to the previously known design,

2 shows a view of the ceiling above the branch channels with a central poke opening and shown in dashed lines the ideal position of the poke opening,

Pig, 3 a vertical section through two manholes of one Shaft furnace with three shafts according to the invention,

Fig. 4 is a horizontal section along the line IV - IV of Fig. 3 and

FIG. 5 shows a view of the ceiling shape over the branch channels in the shaft furnace according to FIG. 3 with poke openings.

Fig. 1 and 2 relate to the known design of the shaft furnace , It has three shafts 1, 2, 3 with ring channels 4, 5 and 6. The ring channels 4,5,6 are each with a branch channel the axes 7, 8, 9 in the center of the three shafts 1,2,3 with each other tied together.

The shape of the ceiling to be erected over the branch ducts is shown in FIG. The arrangement of poke openings would be beneficial on the axes 7, 8, 9 of the branch channels, as shown in dashed lines, this would in each case the vault construction too weak, which is why there is usually a single poke opening at the intersection of the three axes of the canal 7, 8, 9 arranges.

In Fig. 3 and 4, a shaft furnace is shown in which the branch channels are designed differently from the embodiment according to FIGS are,

309846/0777

~ 6 τ.

The shafts filled with material to be fired are again designated by 1, 2 _r 3, in which a preheating zone A, a burning zone B and a cooling zone C are distinguished. The upper part of the preheating zone A with the device is no longer shown in FIG. 3, as is the lowermost part of the cooling zone C and the discharge device. The shaft 1, in which some fuel supply pipes 11 are indicated by dash-dotted lines, is the heated shaft in which with arrow 10 the supply of the supply. combustion air and the transition of the flue gases into the annular duct 4 is indicated by arrow 12. The flame or the smoke gases flow in shaft 1 in cocurrent with the material from top to bottom. The combustion air is fed to the heated shaft 1 above the stone level, i.e. above the preheating zone A. The. Flue gases from the heated shaft 1 enter the annular channel 4 via an embankment 15 formed by the expansion of the shaft cross-section at the end of the combustion zone. The shaft masonry 13 is supported by pillars 14, the supporting arches of which are arranged in the form of a polygon.

The shaft 1 is connected to the shaft 2 by a branch channel 16 and with the shaft 3 by a further branch channel 17 bound. The shaft 2 is connected to shaft 1 by the already mentioned Branch channel 16 and connected to the shaft 3 by a branch channel 18. Correspondingly, the shaft 3 is with the Shaft 1 through the branch channel 17 and connected to shaft 2 through the branch channel 18. It is therefore essential that every shaft is connected to the shaft by a separate branch duct, i.e. the flue gases pass through two branch ducts into the other shafts.

The arrangement of two branch channels per ring channel results already a doubling of the cross-section compared to the previous, single ring channel. The width of each branch channel is in addition, not as statically restricted as with the star arrangement.

309846/077

"7"

The straight vault with which every branch canal is covered is a simple ceiling, the length of which towards the abutment becomes larger and larger, and which is the shortest in the middle part, which in terms of stability and durability is very advantageous, see Fig. 5,

The poke and control openings 19 of a puncture channel can also be arranged in an ideal position without the stability of the Disturb ceiling. The poke openings entered in dashed lines in FIG. 2 would, however, have a very detrimental effect on the stability of the ceilings in the case of a star arrangement, which is why they do not adhere to the operationally most favorable point can be set. The main advantage of the triangular arrangement of the branch channels 16, 17, 18, however, lies in the substantially more favorable flow conditions. The flue gases exiting from the slope 15 into the annular channel 4 flow from one side through the branch channel 16 to the Discharge shaft 2 and from the other side through the branch channel 17 to the shaft 3. The ring channel flows meet in 'in contrast to Star arrangement never on top of one another. The redirection at the fork in the branch channel is also omitted. The vortex formation is at the The triangular arrangement is therefore much smaller, and thus the dust deposits are reduced. There are also no impact surfaces available. The larger duct cross-sections also reduce the speed considerably. With the decrease in Vortex and the reduction in speed also reduce the "mass transfer number" required for the separation of the alkalis and the transition from S0_ to the dust deposits is decisive is. Tests have shown that with a small mass transfer number, the dust deposits consist for the most part of CaO, not very become solid and fall off by themselves when a certain strength is reached. Due to the reduced vortex formation, there is also a any afterburning does not occur until the flue gases re-enter the slopes of the exhaust shafts, which is absolutely harmless.

309846/0777

With the triangular arrangement, the maximum speeds in the ring channels 4, 5, 6 are also significantly lower. With the star connection, the ring duct, which makes up a drain, absorbs all of the flue gases from the heated shaft (the flue gases flow in over 360 of the ring duct); emerge from the shaft: (Indicated by arrows in the figure.) The maximum flue gas speed in the ring duct is therefore only about half of the maximum speed in the case of a star arrangement in the case of a triangular arrangement. The other half of the flue gases flows directly from the slope of the heated shaft to the slopes of the secondary shafts.

The shaft furnace is switched periodically after about 10 to 15 minutes, i.e. the heating is then switched on from one shaft relocated the other, while the previously heated shaft becomes an exhaust shaft. Each shaft is heated for a period and The smoke gases are drawn off through this duct for two periods. All three shafts are shown from below, as indicated by arrows 20 is, cooling air is blown in, which is not used for combustion, but for cooling the fired material.

309846 / Ό777

Claims (1)

Claim Shaft furnace for burning granular material, consisting of three same, in cross-section circular or polygonal shafts which are arranged at angles of 60 and from which periodically a shaft is heated in cocurrent with the descending material, while the flue gases of this shaft through the other two, parallel-connected, unheated shafts in countercurrent, with each shaft has an annular channel in the area between the combustion zone and the cooling zone, the annular channels being at the same level as one another and are connected by branch channels, characterized in that each ring channel (4, 5, 6) of a shaft (1, 2, 3) through a constantly open branch channel (16, 17, 18) is connected to each of the other two shafts, and the location of the branch channels corresponds to the sides of a triangle. 309846/0777 March 27, 1973
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