DE19723911A1 - Low temperature pyrolysis of e.g. lumpy scrap containing low-melting alloy, composites and harmful substances - Google Patents

Abstract

A new unit proposed for low temperature coking, burns off the gas it produces. The novel feature of this design, is a hot gas channel containing a strongly-oxidising pilot burner, which burns off the gas liberated. This gas is burned in counterflow against the pilot and at high temperature. The radiation produced, heats the material being carbonised (the bed) directly. This heating liberates more gas, in a process recycling heat by radiation.

Description

field of use

The invention relates to a device according to the preamble of claim 1.

State of the art

When smoldering, so much heat is added to a combustible solid that it does not melt or burns; the heat is metered into the carbonization with the supply of oxygen. The resulting Smoldering gases are incompletely oxidized and harmful to the environment if they are not burned and cleaned. If, as in the old Meiler process, carbonization and heat flow are rectified, it can only be slow be charred so that the solid is not overheated (burned). High smoldering speeds achieved one, on the other hand, in more modern (smoldering and burning) processes, in which heat is countercurrent to the stripping Carbonization gases and targeted oxygen is applied to the carbonization material. This will be the afterburning The heat generated is used for the smoldering in which the gas flow (carbonization gas + oxygen = hot gas) Solid flow is counter-directed to the heat of the hot gas (heat source) for smoldering the Solid (heat sink) to use. The energy of the hot gas is transferred to the solid by heat exchangers transmitted so that carbonization gas and hot gas do not mix and the oxygen supply for the carbonization can be targeted. Equipment expenditure and heat losses are thus predetermined.

Heat transfer by radiation is widely used in daily use and in technology. However, it is not known that a smoldering process is autogenous from the thermal radiation of afterburned smoldering gases can be operated. Such a process would be energy efficient and economical, but difficult to do Realize because high temperatures for afterburning but low for charring Oxygen offers are required.

Disadvantages of the prior art

The use of partitions (heat exchange through surfaces or pipe walls) entails costs Investment and operation compared to the arrangement according to the invention, where a heat exchange between Afterburning zone and solid to be smoldered can be done without partition walls. Especially for Relatively small amounts of solids to be smoldered are simple constructions without a heat exchanger more economical.

Object of the invention

With the method according to the invention, plastic-ceramic-metal composites with dangerous ingredients are said to be and low-melting metal alloys are both energy-saving and environmentally safe. It is therefore necessary for such feedstocks, the solid to be smoldered at not too high and the Oxidize smoldering gases at not too low temperatures. The heat of the smoldering gas post-combustion should used for the heat demand when smoldering in a simple way without heat exchanger partitions will.

Solution of the task

The afterburning zone is arranged so close to the smoldering material and the pilot light is set so small that the required smoldering heat only by radiation from the afterburning zone on this and that Smoldering gas flow can be transmitted in the opposite direction.

Advantages of the invention

Because the countercurrent heat exchange required for an energetically favorable carbonization between Afterburning zone and solid to be smoldered can only take place by radiation Conventional heat exchange devices are no longer required. By using the fuel content of the insert a solid smoldering residue at low temperatures and Oxygen partial pressures and at high temperatures and oxygen partial pressures a completely afterburned Hot gas are generated. For smaller amounts of solid to be smoldered, this is compared to the state of the Technology more economical.  

description

A pilot burner ( 4 ) is arranged in a duct ( 1 ) through which hot gas ( 2 ) is drawn off with a blower, the flame of which is strongly oxidizing and is directed towards the carbonization gases. A post-combustion zone ( 5 ) with high temperatures of up to approx. 2000 ° C. therefore forms in front of the nozzles of this burner; in it the countercurrent smoldering gases ( 6 ) are burned together with either the excess oxygen of the burner or additionally with oxygen from the central nozzle ( 7 ) of the burner or from secondary nozzles ( 8 ). The hot gas duct and burner are dimensioned such that the carbonization gases can leave the device only via the afterburning zone as completely burned hot gas ( 2 ). Neither the pilot flame nor the afterburning zone convectively touch the carbonized material ( 3 ); rather, it is heated by thermal radiation ( 9 ) from the afterburning zone. Since the above-mentioned oxygen flows can be metered and directed towards the char ( 3 ), the temperature can be low there, e.g. B. be kept at 700 ° C. At the beginning of a smoldering process, the burner must be briefly moved closer to the smoldering material so that the afterburning zone can form (ignition). After that, the smoldering and the afterburning are almost autogenous except for the small pilot light.

Claims (6)

1. Apparatus for smoldering and for smoldering gas afterburning, characterized in that in a hot gas channel by a strongly oxidizing pilot burner, a counter-flowing smoldering gas is post-combusted at high temperatures, which is produced at a low temperature from the smoldering material by the heat radiation from the post-combustion zone. 2. Central oxygen nozzle according to claim 1, characterized in that the pilot light due to its small diameter and high pressure can penetrate without any noteworthy mixing and can supply oxygen to the char from above. 3. secondary nozzles according to claim 1, characterized in that they are attached in the vicinity of the char, so that bulky use also can be blown laterally or from below with oxygen. 4. Rectangular hot gas duct with several pilot burners according to claims 1 and 2, characterized in that larger carbonization widths are carbonized with these in a parallel arrangement can. 5. Movable pilot burner according to claims 1, 2 and 4, characterized in that one or more such pilot burners are installed in one or more lances that can be moved in the direction of the char and back by approx. 0.5 m. 6. lances according to claims 1, 2, 4, and 5, characterized in that these are provided with water cooling, which the built-in burner and Protect the lances from overheating.