DE441823C - Firing with an afterburning chamber connected to a firing chamber - Google Patents

Description

Firing with an afterburning chamber connected to a fire chamber. . The invention extends to furnaces specifically for low-value fuels, Bagasse, sawdust and the like, which have been difficult to burn industrially offers, but also for burning other fuels, e.g. B. coal, with increased Efficiencies.

For such fuels, firing systems have so far been the best with an afterburning chamber connected to a fire chamber. These suffered but the survived incomplete ignition and combustion, what after employed Try to find the wrong shape of the chambers and supply the secondary air immediately was returned to the afterburning chamber.

In order to avoid these disadvantages, the rear wall is according to the invention the post-combustion chamber as a radiation or reflective wall and the post-combustion chamber run higher than the fire chamber, with the combustion air coming through the Firebox is fed. The ceiling of the fire chamber is particularly advantageous towards the post-combustion chamber designed ascending. The as Radiant or reflective wall formed rear wall of the afterburning chamber arched be designed or the ceiling of the fire chamber and the radiation wall a dome room form.

Five exemplary embodiments are shown schematically in the drawing.

Fig. I is a longitudinal section of one embodiment of the new furnace in connection with a steam boiler.

Fig. 2, 3, 4 are longitudinal sections through other embodiments.

Figure 5 is a section through another version with a dome-shaped fire chamber. The furnace equipped with a plan grate 13 is arranged as a so-called pre-furnace at the front end of a steam boiler. In the embodiments according to Fig. Z to 3, the fire chamber is delimited above the grate surface by a flat, brick vault 15 or 38.

The furnace according to Figure 4 has a curved, refractory front wall, to bring about a better reflection of the heat on the fuel bed. at In the embodiment according to Fig.5, the furnace has a circular plan, and the wall. 53 is arranged at a distance from the grate.

Pour sawdust or other fuel onto the flat grate 13 one or more funnels 21 above the center of the grate are in the brick vault 15, 38 or 41 arranged. The poured fuel then settles in the form of a conical heap on the grate. In the In the embodiment according to Fig. 5, several such charging hoppers 43 are provided, As a result, the fuel in several conical piles the grate covered.

The actual fire chamber 12 is followed by: according to the invention a higher designed further post-combustion chamber 22, the rear wall of which is a radiation or mirror wall. This extended post-combustion chamber 22 stands with the actual fire chamber 12, d. H. the space above the grate, as a whole Height and width in direct connection. The combustion chamber 22 is wide enough to ensure complete combustion of the volatile constituents of the fuel secure before they come into contact with the relatively cool boiler walls come. So that the back wall of the post-combustion chamber is set in embers and Can radiate heat, it is at a certain distance from the rear end of the Arranged grate. By radiating from the rear wall and the side walls and the reflected heat is used to heat the fuel on the grate. dried and subjected to effective gasification. This occurrence is still supported by the ceiling of the fire chamber, which in the embodiment according to Fig. i and 3 as a sloping ceiling 15, in the embodiment according to Fig. 2 as a flat corner 38, in the embodiment according to Fig. 4 as a vault - 41 of concave cylindrical Form and is designed as a dome vault according to Fig. So that the burning of the Gases taking place in front of these heat-radiating walls is the floor 23 of the afterburning chamber approximately at the same height as the grate surface and forms in a sense a continuation of the grate between the rear end of the latter and the vertical radiation wall. This means there are dead spaces in which there is no combustion can take place, avoided, and the bottom 23 will also absorb heat and radiate upwards.

In some cases, such as B. in the embodiment according to Fig.4, can the bottom 24 of the combustion chamber -s 22 are slightly higher so that it is behind the Grates form a low wall in the manner of a fire bridge. This increase in the soil however, must not impair the effective space of the combustion chamber 22, which is why the bridge is kept as low as possible.

According to Fig. 1, 3, 4, the boiler to be heated is arranged above the combustion chamber 22 and part of the boiler wall is exposed to the heat radiated from the combustion chamber directly through a channel 25 or 45, 49. According to Fig. 1, this channel 25 is partially formed by a continuation of the wall 16 and a wall 46 opposite this, which is built on the rear end of the fire vault 15, while in the embodiment shown in Figs. 49 is also formed by vertical walls 47 and 48 or 50 and 51, which form the continuation of the fire vaults 15 and 39 or 40 and 41. These fire channels are relatively short and open into a heating channel 27 running below the boiler.

The pre-drying and degassing of the fuel takes place here Executions in particular through the heat radiated back from the walls and vaults instead of. With some fuels, e.g. B. in the case of long-flame, they become the charisma of heat serving wall surfaces be larger, while with other fuels the Radiated heat is held together and prevented more in the combustion chamber it must be that a larger part of the heat is radiated directly to the boiler walls will. For this purpose, the design according to Fig. 2, in which between horizontal ducts are provided for the extended combustion chamber and the boiler, so that the heat rays cannot reach the boiler wall in a straight line. The channel 28, 3 i is knee-shaped here. This will also allow for a better blending of the still unburned gases with the air they still contain and thus a perfect one Combustion achieved. At the same time, this design of the exit end The enlarged combustion chamber kept the heat together better for the purpose of reflection and especially with long-flame coals with a high moisture content, a perfect one Mixing and combustion of the fire gases ensured.

The heat-absorbing and reflecting walls exist preferably made of: refractory bricks, but of course other refractory bricks can also be used Substances are used, e.g. B. rammed earth, refractory mortar o.

According to Fig. 5 arranged in the center of the fire and combustion chamber 22 rust 1 3 is surrounded in the same amount of a refractory, ring-shaped floor 54 which extends to the side walls 53, which are designed as dome upwards. Approximately in the middle of the domed vault is the cylindrical discharge duct 55, around which the pouring openings 43 for the fuel are arranged.

Claims (4)

PATENT CLAIMS: i. Firing with a fire chamber adjoining Nachb.rennkammer, characterized in that the rear wall (16, Fig. I) of the post-combustion chamber (22) as a radiation or reflective wall and the afterburning chamber higher than that Firebox (i2) is designed, with the combustion air passing through the firebox alone is fed. 2. Firing according to claim i, characterized in - that the ceiling (15, Fig. I) the fire chamber rises obliquely after the combustion chamber. 3. Firing according to claim i, characterized in that the as. Radiant wall (39, Fig. 3) - formed rear wall of the afterburning chamber is arched. 4. Firing according to claim i and 3, characterized in that the ceiling (4 i, Fig.4) of the celebration chamber and the radiation wall (40) of the post-combustion chamber form a dome space.