DE526860C - Process and device for ash removal from furnace systems by means of pressure delivery pipes - Google Patents

Description

Method and device for ash removal from furnaces by means of Pressure delivery pipes The invention relates to a method and an apparatus for ash removal from combustion systems by means of pressure pipes. Such high pressure ash removal work so far in general in such a way that the pressure lines remove the Ashes get spilled or by means of their ejector effect suck in generated vacuum yourself. In any case, there is the disadvantage that easily more ash flows into the pressure line than it can handle, so that blockages enter. On the other hand, this unregulated ash allocation can cause the There is no ash at all, so that the pressure line runs empty and unnecessarily much consumed by the pressurized subsidy.

Attempts have been made to open the ashes to a greater or lesser extent to regulate the trigger slide and to slide it over the sloping funnel surfaces to sprinkle. In other versions, the ashes are put into the delivery line together with the inflowing conveying air by means of slides or valves built into the pipes regulated. Even with the known sinks, in which the outlet mouth of the downpipe closed by the ash cone and the ash of the delivery line through under The precise regulation is the precise regulation of the flow of water jets blown into the ash cone the amount of ash to be discharged in each case difficult. According to the invention, the amount that accumulated under its angle of slope and washed away into the pressure delivery line Ash regulated by jets of water blown from above onto the supporting slope. For this are according to the invention above the ash support surface forming the sole of the between Ash funnel and pressure delivery line provided housing water jet nozzles provided, the opening between the inlet connection and the inlet opening leading into the pressure delivery line lie above the ash cone and the jet direction is adjustable.

A ash removal device serving to carry out the method according to the invention is shown schematically in the drawing as an example in vertical longitudinal section.

The ash funnel a of the boiler furnace, which can be closed by slide b in a known manner, is followed by a pipe c, which opens out at the bottom in a housing d which is closed on all sides. This housing d has a moderately inclined bottom, the deepest end of which is formed by a grate e. Below the grate e, the inlet f leads to the housing g, in which the pressurized water nozzle la conveys into the line i. The pressurized water nozzle h is fed in a known manner from a high pressure water line j. The inlet f to the flushing nozzle housing g can be closed by a non-return valve k. In the housing d, before the confluence of the tube c, a slide l extending over the entire width of the housing is arranged, which is adjustable in height and leaves a passage gap n2 free at the bottom. The height adjustment of the slide and thus the extension L of the gap in occurs from the outside of a crank ii out by means of a rack and pinion drive W. In the housing d , water spray pipes o, p are arranged in front of and behind the ash inlet c, which are fed from a line q. Both spray pipes o and p or at least the front p can be pivoted in such a way that the direction of the spray water jets emerging from them can be changed. The pipe p can be designed as a rotary valve and connected to the slide l in such a way that when the slide l is pulled up, it turns on the water flow from q and changes the direction of the exiting spray water jets during the slide movement. Above the grate e, an opening which can be closed by a cover Y is provided in the housing d , through which the interior of the box d and the grate e are accessible.

Depending on the capacity of the ash hoppers d, the slides b on the ash hoppers' mouths are opened in larger or smaller spaces for ash removal, whereupon the ash flows into the tube c and rests on the inclined bottom surface of the housing d. Depending on the nature of the ash and its greater or lesser tendency to slide and shoot, the slide L is set so high in the housing d that the angle of slope of the ash column determined by the gap m does not yet reach the grate e. The entire ash rests on the bottom of the housing without slipping by itself. D. After the ash has fallen into the pipe c and the housing d, the spray water pipes o and p are turned on. The front water pipe p flushes a constant amount of ash from the slope of the ash column, which can be determined by the slide l, to the feed nozzle housing g. The rear spray pipe o has a supporting effect in a known manner by wetting the lower support surface of the ash and causing the ash column to slide so far that the slope angle in front of the gap m in the area of the front spray pipe p is always restored. By appropriately pivoting the pipe p, the direction of the exiting spray water jets can be changed so that they always hit the ash slope angle and more or less wash away from it. If the ashes z. B. in such a way that an upper boundary line I is formed, the rinsing water jets must exit approximately in the direction of arrow I 'in order to reach this angle of repose I. If you pull the slide L higher and widen the gap, it is sufficient to let the water jets emerge in the direction of the arrow II 'in order to reach the angle of repose II, which now extends further forward. The spray pipe p can be inevitably connected to the slide l in such a way that initially, when the slide L releases only a very small gap in, the water jets emerge in the direction of the arrow I 'and are then automatically pivoted when the slide l is pulled up so that the spray water jet direction II 'is achieved according to the taper angle now extending further forward.

The device described is an automatic uncontrolled The ash to be removed from the pipe c is prevented from shooting out. The ashes will rather, by the dosing water jets in a controllable amount in such a way to the flushing nozzle housing g assigned that this always remove the flooded amount of ash and not can clog. At the deepest point of the grate c, the jets of rinse water washed away those ashes and cinder blocks too big to get through to go through the crevices of the grate e. They can be placed on the wire rack after opening of the lid r are crushed so far that they can pass the grate gaps and do not block the flushing line behind it. As a result of the inclined position Rinse the grate e and the spray water jets on the other side this the front end of the grate always free, so that the retained residues never cover the entire grate surface and prevent free passage.

The non-return valve k in the flushing nozzle housing g is operated by hand or automatically then actuated when the flushing line i is blocked once. The closed flap k then prevents the pressurized water flowing further out of the feed nozzle la can climb up into the furnace flues.

The invention is also suitable for ash removal systems in which on The outlet of the ash funnel a no slider are arranged, but the ash accumulates immediately in the housing d and the downpipes c.

Claims (2)

PATENT CLAIMS: i. Process for ash removal from combustion systems by means of Pressure pipes with embankment of ash in one between Ash funnel and delivery line arranged housing, characterized in that the amount of pent-up at their angle of slope to be washed away into the pressure delivery line Ash regulated by water jets directed towards the discharge side of the ash slope will. 2. Device for carrying out the method according to claim i, characterized in that that above the inclined sole of the between the ash funnel, which forms the ash support surface and pressure delivery line provided housing (d) water jet nozzles (p) provided between the inlet connection (c) and the one leading into the pressure delivery line Incidence opening (f) lie above the ash cone and its direction of jet is adjustable.