DE91332C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

CLASS 24: Combustion systems.

AUGUST KRIPPEL in VIENNA. Combustion system.

Combined the combustion system causing smoke consumption according to the present invention efficient air supply with high heating temperature and allows forcing within wide limits.

FIGS. 1 to 5 illustrate such an underfiring in longitudinal section, cross-section, Grundrifs and in two views,

Fig. 6 and 7 such an internal furnace,

Fig. 8 and 9 such a furnace for locomotives, as well as for ships, which with Locomotive boilers are provided,

14 to 15a such an underfiring, in which the cleaning door is heavily exposed to the effects of fire (e.g. Babcock & Wilcox boilers),

Fig. 10 to 13 in all systems for Application coming fire door and

Fig. 16 and '17 the pipe connection to the water space of the cleaning door.

The vaults α are made of fire-resistant, heat-poorly conductive material (chamotte, magnesite, dinosaur stones) so that heat is not given off by radiation to surrounding iron walls that are wetted by the water and the temperature in the heating room itself is reduced during the development of the fuel gases etc.).

The heating temperature of the ash chamber A is used to preheat the secondary air; the associated cooling of the same contributes to the preservation of the grate. The air tunnels b (Fig. 1, 2, 3 and 14), which are located just below the grate next to the ash chamber and are only separated from the ash chamber by iron plates b ' , are used for this purpose. These iron plates absorb the heat radiating downwards from the grate very quickly and share it with the air in the air tunnel, which is kept as spacious as possible; the air is forced by the cold outside air, which rushes in after the air slide r has been opened, to the narrow gap d made on the rear wall of the furnace, from which it emerges at great speed into the furnace. This gap d has one against the combustion chamber tapering cross section and is mounted so that relatively cold air DAF as high as possible above the burning material layer, but just below the spanning the grate refractory arch α preferably pulled back from the gratings in the direction against the Feuerthür steps into the very hot furnace; there the air suddenly expands and mixes intimately with the heating gases it encounters from the fire door. As a result, the air-sucking activity of the forge is already relocated in front of the furnace, and a great rate of entry into the boiler room is gained not from the ash-room but from the outside, that is, cold air.

But the c against the Feuerthür radiant, so harmful heat is verwerthet in the same · sense by also preheats from without passing through the Feuerthür air that the same back in the chambers and is brought hither before in great possible to height enters the combustion chamber above the grate. The cooling of the fire door by the fresh air entering is necessary at the high heating temperature.

The mixing of the fire gases with the secondary air entering through the fire door c is "effected by the saw-like or step-like construction of the vault α , in that the gases accumulate at the individual corners and assume a whirling movement.

The number of air tunnels b depends on the size of the boiler and the local conditions.

In the case of very poor coals, heavy slagging of the grate and particularly forced firing, an increased supply of secondary air through the gap d can be brought about by opening the valve e (Fig. 4) and allowing steam to flow out of the perforated pipe f located behind the gap d , which then, acting as an injector, entrains atmospheric air into the boiler room.

After opening the valves g (Fig. 4), steam is also allowed to escape under the grate through the perforated tubes h. This steam penetrates the slag, the formation of which it restricts, loosing it at the same time and opening up new paths for the primary air coming from below, brought to greater expansion by the embers.

The continuous admission of secondary air would result in a large excess of air, i.e. a waste of fuel. That is why the secondary air supply only takes place for very short periods of time intermittently and without the heater being involved.

As soon as the fire door c (Fig. 10 to 12) is opened, its bracket i (Fig. 3) rotates and, with the aid of the connecting rods k and z ^1, opens the faucet vortex /, whereby the hollow sheet metal cylinder η is filled by means of the pipe m. After the cylinder n is filled, it is heavier than the slide r of the air tunnel b \ slide r is therefore pulled up and opened by the sinking cylinder. At the same time, a valve 0 at the bottom allows the water to flow out of the cylinder η into the cylinder ρ below, whereby the cylinder η , which has been emptied within a certain time, becomes lighter than slide r again, and is therefore pulled up by it. The water flows out of the cylinder ρ through the pipe q .

The drainage of the water from the cylinder η in the receiving cylinder ρ respectively. the time required to keep the slide r open can be regulated once and for all by setting valve 0 so that both the start and the interruption of the secondary air admission take place automatically.

To protect the boiler plate against the jet flame, the vault s (Fig. R, 2, 8 and 14) is attached.

The fire door c (Fig. 10 to 13) has a space divided into two chambers ^{by the partition c 1;} the air enters the first chamber at c ³ above, is led around the septum c ¹ below, enters the. second chamber and through gap c ⁴ at such a height above the fuel in the furnace that a direct brushing of the fuel with fresh air is excluded. The fire door is effectively cooled by this air flow.

Fig. 14 shows a riveted to the Putzthür t water tank and with a water tube boiler. Water flows in through pipe ν and through pipe w it flows out into the container used for boiler feeding.

These pipes are arranged in such a way that they can be easily removed if this is necessary to open the cleaning door for cleaning the boiler. For this purpose, the inlet and Abflufsstücke are the water rinse in the form of stirrups ν and w prepared (Fig. 14 to 17) in which the pipe sections by means of screws χ and Kautschükdichtungj- 'hermetically to the mouth pieces \ geprefst be. Since the formation of steam in the water tank cannot be ruled out at the high heat of this furnace, it is arched at the top and a steam discharge pipe ^ ¹ (Fig. 15 a) is led into the ash chamber from the highest point of this arch. This construction not only maintains the cleaning door, but also creates a preheater for the feed water.

Claims (2)

Patent Claims: • i. Firing system with smoke consumption through automatically regulated air supply immediately after opening the fire door, characterized in that when the fire door is opened, an automatically regulated slide for air from outside, and in the case of internal firing (Fig. 6 and 8) by leading from the rear to the fire bridge Unterfeuerungen by stored next to the ash fall, from this only separated by iron walls air tunnels b so from the fire bridge respectively. the rear wall of the furnace allows it to emerge against the direction of pull of the fire gases below one from the fire door to the fire bridge or Back wall of the furnace to be extended vault, which is designed in a saw-like manner for intimate mixing of the secondary air entering through the fire door with the fire gases. 2. In the firing system protected under 1. for the automatic adjustment of the air supply, the connection of the fire door c with a bracket i, which when the same is opened by rod k and lever z ¹ a Faucet / opens and thereby the filling of a movable container η connected to the air tunnel slide r causes so that the container, which has become heavier than the air tunnel slide, lifts the same and thus the escape of secondary air from the fire bridge and / or. Rear wall of the furnace allows whereupon abfliefst again in the Maafse, as the water from the cylinder n, a selbstthätiges fall of the slide and thus Reasoning of the air tunnel occurs. In addition 3 sheets of drawings.