DE1087742B - Cyclone firing - Google Patents

Description

Cyclone furnace The invention relates to a cyclone furnace, consisting of from several wall-cooled, circular cylindrical furnace muffles with swirl flow the fire gases, which flow out of the furnace muffle tangentially and tangentially flow into a circular cylindrical, wall-cooled afterburning chamber, which is axially parallel is arranged to the furnace muffle, and consists in that for each furnace muffle a special afterburner .gehört, which is located above the associated and with an approximately horizontal axis arranged furnace muffle.

Feuerunigen with two connected in series in the flow of fire gas Cyclone grouches are known. There is also a cyclone furnace with several muffles and several afterburning chambers, also designed as cyclone muffles, are known which the fire gases exit tangentially at the end of the first muffle and tangentially in enter the afterburning chamber. However, this known furnace has coherent Rooms, whereby the fire gases are released during partial load operation with only one initial muffle distribute the two second muffles, and unequally.

With cyclone firing, the muffles that are in operation are used held at such a high temperature that the slag is liquid. During partial load operation Therefore, the load may only be reduced to such an extent that the slag is also in the afterburning chamber still remains liquid. According to the invention, each furnace muffle is a special one Afterburning space is assigned, the partial load can be reduced further than in the known furnaces in which several muffles are connected to a common afterburning chamber are connected.

In a known furnace with two series-connected in the fire gas stream In the muffles, the slag flows out of the upper muffle over the entire circumference into the equiaxed arranged lower muffle. The process is hardly any different than with any firing with a vertical axis where the slag flows down the walls. at other known furnaces with a cylindrical one parallel to the axis of the muffle The afterburning chamber must have a separate slag outlet because it is optional one or the other of the connected firing muffles may be out of order.

According to the invention, the afterburning space is above the furnace muffle arranged so that the fire gases through the only connection opening without loss of shock can flow from the furnace muffle into the afterburning room while the slag from the afterburning room against the flow of fire gas on the walls into the furnace muffle flows back. This process is in spite of the high flow velocity of the fire gases possible because their speed is lower in the edge zones and because the slag, even if their surface layer flows slowly, flow faster under it can.

In order to achieve a space-saving arrangement, further training the invention the two muffles are arranged approximately with the end bottoms in one plane, so that the main direction of movement of the fire gases in the direction of the spin axis in the Firing muffle that is opposite in the afterburning chamber.

The afterburning chambers can be placed in a common, wall-cooled radiant room open out, where they are advantageous as an approximately right-angled bend with the fire gas outlet are designed upwards in order to also derive the slag occurring in the radiation room to be able to. Each afterburning room works best with one in the upper one Central, nozzle-like fire gas outlet opening in the front wall Radiation space over, so that the mutual influence of the individual furnace muffles is low.

Openings can be provided in the outer wall of the neck of the afterburning chamber through which the fire gases tangentially and in the direction of swirl third air can be used, if this is used for post-combustion or for temperature control of the flue gases should be required.

In contrast to the known arrangement in which a radial opening is provided in the end wall, the slag outlet of the first muffle can protrude in a manner known per se in the case of melting chambers and merge directly into the slag drainage shaft, which is sealed off from air. A cyclone furnace designed according to the invention is shown in Fig. 1 in axial section, in Fig. 2 in section perpendicular to the axis. The first muffles 1, 2 are encased in circular cylindrical jackets 3, 4. The outer end faces 5, 6 are conical and merge into the cylindrical burner heads 7, 8, to which the mixture of solid, granular fuel and carrier air is supplied in an adjustable amount through channels 9, 10 so that the nozzles 11, 12 are approximately tangential merge. In a similar way, the second air is supplied to the muffles in a controllable amount through the channels 13, 14, which open with the nozzles 15, 16 approximately tangentially to the jacket 3, 4 and in the same direction of swirl as the fuel. On the other end faces 17, 18 the jackets 3, 4 have openings 19, 20 through which the muffle chambers 1, 2 are connected to the afterburning chambers 21, 22. These muffles are also circular cylindrical. Their jackets 23, 24 are designed in the same way as the jackets 3 and 4. The end walls 17, 18 also form the end walls of the muffles 21, 22 Immerse the water seal in the water cups 29, 30. The muffles 21, 22 are designed as right-angled pipe bends, the end walls 31, 32 of which each have a nozzle-shaped indentation 33, 34 and with them form the transition to the radiation space 35 of the fired steam generator. Third air is blown tangentially into the afterburning chambers 21, 22 in the area of the nozzles 33, 34 through channels 36, 37 with nozzle openings 38, 39, if there is a need to burn flycoke from the flame.

In order to achieve good controllability of the furnace at part load, the diameter of the second muffle is advantageously selected to be smaller than that of the First muffle, so that in combination with the action of the nozzles 33, 34 an easier Traffic jam stops. The liquid slag flows to the openings 25, 26 even if it still accumulates in the funnel 35. The drainage is favored when the axes the first muffles 1, 2 and the second muffles 21, 22 against the slag outlet openings 25, 26 drop off slightly.

Claims (7)

PATENT CLAIMS: 1. Cyclone furnace, consisting of several wall-cooled, circular cylindrical furnace muffins with swirl flow of the fire gases, which flow tangentially out of the furnace muffle and. flow tangentially into a circular cylindrical, wall-cooled afterburning chamber, which is arranged axially parallel to the furnace muffle, characterized in that a special afterburning chamber belongs to each furnace muffle, which is located above the associated furnace muffle with an approximately horizontal axis. 2. cyclone furnace according to claim 1, characterized characterized in that the main direction of movement of the fire gases is in the direction of the spin axis in the furnace muffle that is opposite in the afterburning chamber. 3. Cyclone firing according to claim 1, characterized in that the afterburning chambers are in a common wall-cooled radiant room open out. 4. cyclone furnace according to claims 1 and 3, characterized in that the afterburning chambers as approximately right-angled Elbows are formed with the flue gas outlet upwards. 5. Cyclone firing according to claim 4, characterized in that the afterburning chamber is in the overhead Front wall has a central nozzle-like fire gas outlet opening. 6. Cyclone firing according to claim 5, characterized in that in the outer wall of the neck of the afterburning space Openings are provided for the tangential inlet of third air in the direction of swirl. 7. cyclone furnace according to claim 1, characterized in that the slag outlet nozzle the first muffle protrudes from the front wall of the muffle and directly into the under air exclusion standing slag drainage shaft passes over. B. cyclone furnace according to claim 1, characterized characterized in that the clear diameter of the afterburning chamber is smaller than -is the one who grudges fire. Publications considered: German patent specification No. 397 548; British Patent Nos. 338 108, 552 747; U.S. Patents No. 901232, 1313 779, 2,573,910; "Energie" magazine, 1950, p. 4344.