EP0751347A1 - Furnace - Google Patents

Abstract

The fuel such as wood, wood waste, bark, bio waste, chipboard waste is conveyed by a feed grating (4) conveying the fuel continually through the various zones of a primary part of the combustion chamber. A secondary area above the primary part has extra air inlets (8). The outlet (9) to the combustion chamber (5) above the secondary area opens from underneath into a lower part of a post-combustion chamber (10) with a longitudinal axis sloping in relation to a horizontal plane, and an outlet (11) at the top end of the longitudinal axis. A fan unit (13) in the post-combustion chamber causes the combustion gases to flow in a rotary motion around the longitudinal axis of the chamber. The deposited particles on the wall of the chamber slip towards the outlet of the combustion chamber.

Description

The invention relates to a furnace for solid fuel, in particular for organic solid fuels, such as wood, wood waste, bark, bio-waste, waste from the production of chipboard or the like. With a continuously shifting the fuel and through different zones - for example, dry -, Burning and burn-out zone - a primary area of a combustion chamber leading feed grate with controllable underwind supply, a secondary area of the firing area arranged above the primary area in the firing area with additional air supply and an exit of the firing area arranged above the secondary area.

Such combustion plants are generally known, cf. e.g. DE-AS 23 59 730 and DE 44 26 357 A1. The systems described in these publications are particularly intended for the incineration of waste or waste.

However, other firing material can also be used in such or similar plants. For example, wood chips can be thermally recycled, such as those that occur in large quantities in the wood processing industry. The moving grate can have fixed and moving grate bar rows arranged in a step-like manner, in order to achieve a particularly effective shifting of the firing material and an optimal stoking effect. In addition, such a grate can work in the individual grate sections with a variable transport speed in order to adapt the residence time of the firing material in the different zones of the primary area of the combustion chamber to the respective needs or qualities of the firing material.

A cyclone combustion chamber can be provided according to DE-AS 23 59 730 in order to ensure low-emission gases. According to DE 44 26 357 A1, a rotatable nozzle roller is arranged in the smoke exhaust.

Despite the low pollutant emissions, a further reduction in the proportion of pollutants remains desirable.

It is therefore an object of the invention to optimize combustion plants of the type specified at the outset with regard to low pollution.

This object is achieved in that the exit of the combustion chamber opens from below, preferably essentially radially, into a lower region of a post-combustion chamber designed as a swirl chamber with a longitudinal axis inclined to a horizontal plane and an outlet arranged at the upper end of the longitudinal axis.

The inclined arrangement of the afterburning chamber significantly reduces the vertical movement component of the flow of the combustion gases compared to the mean flow velocity in the direction of the longitudinal axis of the afterburning chamber, with the result that the mean sinking velocity of entrained fuel particles relative to the combustion gases becomes greater than their mean flow velocity in the vertical direction. Insofar as the firing material particles then fall onto the sloping walls of the afterburning space before complete combustion, they can due to the sloping arrangement like sliding back on a slide to the exit of the secondary area of the combustion chamber, where they are caught again by the flow of the combustion gases and fed back to the turbulent eddies of the combustion gases which are constantly maintained in the post-combustion chamber.

All in all, extremely long dwell times in the post-combustion chamber are thus achieved for difficult-to-combustible residual particles of the fuel, so that a complete burnout or complete gasification can be expected as a result.

The practically dust-free combustion exhaust gases thus have the further advantage that the heat exchangers connected downstream of the afterburning chamber, which serve to use the heat of the combustion gases, can only become slightly dirty and thus work with high efficiency.

Otherwise, with regard to advantageous features of the invention, reference is made to the claims and the following explanation of the drawing, on the basis of which particularly preferred embodiments of the invention are described.

The single figure shows a schematic sectional view of a large combustion plant according to the invention.

The firing part of a boiler system shown in the drawing has, among other things, a fuel feed 1 and a chute 2 with hydraulically operated flaps 3, so that fired material can be directed onto a stair-like feed grate 4 which leads from the chute 2 downwards and forms the underside of a combustion chamber 5 . From below, the grate can be subjected to underwind in a controlled manner, a zone-by-underwind regulation being possible in order to supply the combustion material with the required or desired amount of combustion air. The tubular rods can be pushed back and forth by means of a hydraulically operated frame system in order to transport the firing material while shifting in the direction of the lower end of the feed grate 4. In this way, the fired material is moved through a drying zone adjoining the chute and through a firing zone to a burnout zone at the lower end of the feed grate 4, where the incombustible slags are then thrown onto a wet conveyor line 7, which also has ash falling down through the feed grate 4 is promoted. If necessary, this rust diarrhea can also be fed pneumatically to the combustion chamber.

The combustion chamber 5 extends from a primary area above the feed grate 4 via a secondary area, into which additional combustion air is blown through separate air inlets 8, to an outlet 9 which, from below, essentially radially, into the lower area of an afterburning chamber arranged with an inclined longitudinal axis 10 opens. This afterburning chamber 10 has an essentially cylindrical interior, at the upper end of which an outlet line 11 leads to a boiler (not shown).

At the lower, essentially closed end of the post-combustion chamber 10 there is a fan unit 13 driven by an electric motor 12, with which a turbulent vortex flow rotating about its longitudinal axis can be generated within the post-combustion chamber 10. The blower unit 13 can be a blower or paddle wheel driven by the electric motor 12, the paddle elements being able to be formed by links of chain parts which are each held at one end on a hub driven by the electric motor 12 and the free ends of which circulate the hub can be stretched radially outwards by centrifugal forces. A heat shield 14 can be arranged on the side of the blower unit 13 facing the afterburning chamber 10 in order to protect the blower unit 13 against direct heat radiation from the afterburning chamber 10.

In the area of the blower unit 13, a stoneable air supply 15 opens into the post-combustion chamber 10 in order to supply additional combustion air on the one hand and to be able to quickly mix this air with the combustion gases in the chamber 10.

The outlet 16 of the chamber 10 has a significantly reduced cross section compared to the chamber 10, so that the vortex flow generated by the blower unit 13 only has a larger movement component in the exit direction in the region of its center adjacent to the longitudinal axis of the chamber.

Due to the vortex flow, particles entrained by the combustion gases in the post-combustion chamber 10 are kept as far as possible from its central axis and are shipped into areas near the wall. As a result, these particles can practically not reach the outlet 16 of the afterburning chamber 10. The same applies to particles in the Area of the central axis of the post-combustion chamber 10. Due to the inclined arrangement of this room 10, the vertical component of the gas flow in this area is relatively small, so that the particles can sink down into the area of the vortex flow.

If the particles hit the inner wall of the room 10, they will at least partially slide down to the exit 9 of the combustion chamber 5 and, if necessary, be carried back into the room 10 until they have been completely gasified. Even if these particles adhere to the inner wall of room 10, complete gasification can be expected after some time.

Insofar as the particles consist of completely burnt-out and non-gasifiable ash, they can form a coating on the inner wall of room 10 over time. This coating must then be removed during inspections of the system. However, due to the vortex flow in the afterburning chamber 10 or due to its inclined arrangement, only a very small proportion of these fly ash particles can get into the outlet line 11 and thus contaminate the downstream heat exchanger.

Overall, the particles have a very long dwell time in space 10, so that with a complete one Post-combustion can be expected or the post-combustion chamber 10 acts in the manner of a particle barrier upstream of the output line.

Claims (4)

Firing system for solid fuel, in particular for organic solid fuels, such as wood, wood waste, bark, organic waste, waste from the production of chipboard and the like, with a layer that continuously reshuffles the fuel and through different zones - e.g. drying, burning and burnout zone - a feed grate leading a primary area of a combustion chamber, a secondary region of the combustion chamber arranged above the primary region in the furnace with additional air supply and an outlet of the combustion chamber arranged above the secondary region,
characterized,
that the outlet (9) of the combustion chamber (5) opens from below into a lower region of a post-combustion chamber (10) designed as a swirl chamber with a longitudinal axis inclined to a horizontal plane and an outlet (11) arranged at the upper end of the longitudinal axis. Firing system according to claim 1,
characterized,
that the outlet (9) of the combustion chamber (5) is arranged obliquely to the longitudinal axis of the afterburning chamber (10). Firing system according to claim 1 or 2,
characterized,
that the post-combustion chamber (10) is provided with a vortex or blower unit (13) which excites the combustion gases into a turbulent flow which rotates like a vortex around the longitudinal axis of the post-combustion chamber. Furnace system according to one of claims 1 to 3,
characterized,
that due to the gradient of the longitudinal axis of the afterburning chamber (10), the particles deposited on the wall slide to the outlet (9) of the combustion chamber (5).

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