DE2944693A1 - Rotary drum furnace for pyrolysis of garbage - has axial radiant heating tube contg. burner, and separate outlets for pyrolysis gases and coke - Google Patents

Abstract

The drum furnace is indirectly heated by an axial radiant heating tube (I), which is pref fixed to the drum, or may be free to rotate in the drum. (I) pref contains a tubular baffle employed to circulate hot burner gases inside (I). When the drum rotates on a horizontal axis, it pref contains a helical baffle driving the garbage through the drum. The drum is pref rotated periodically in alternate directions to mix and/or loosen the garbage while still moving the latter to an exit, which is pref in a stationary ring housing. High thermal efficiency is achieved, where burner gases flow in counter-current to the garbage.

Description

Description and explanation of the patent application

'Waste pyrolysis rotary kiln' Waste pyrolysis is often carried out in rotary kilns made, the outer jacket is heated indirectly. However, it is very time-consuming to heat the outer jacket, as it rotates at the same time. In addition, the large surface area of drum furnaces leads to very large energy losses. The amount of insulation required is very great, and exhaust gas routing becomes difficult. According to the invention it is therefore proposed that the pyrolysis of a rotary drum through a central arranged inner steel pipe to be heated.

It is of particular advantage that 1. the radiated from the heating pipe Heat can be conducted in a simple manner in countercurrent to the pyrolysis material 2. the External insulation is only carried out against a very low wall temperature of the rotary kiln must become 3. The rotary kiln is not exposed to any one-sided heat load 4. the heat losses on the outer wall are very low 5. the radiant heater tube can be loaded very heavily 6. no one-sided heating load even when the drum is at a standstill occurs on the drum casing.

The embodiment of such a rotary kiln according to the invention is shown in shown in the accompanying drawing; with 1 the rotating drum with 2 the inner radiant tube with 3 the burner device with 4 a circulating injector arranged in the jet pipe with 5 the transport spiral for the pyrolysis material with 6 the pyrolysis gas outlet with 7 the feed hopper for the pyrolysis material with 8 the slide lock on the rotating drum with 9 the pyrolysis coke discharge with 10 the rotating rings for driving the drum with 11 the labyrinth transition from the rotary drum to the discharge ring.

Furthermore, there is the disadvantage in normal rotary kilns that they have very large surfaces; especially when the dwell times are long, must be reckoned with large surfaces due to the drum extension required for this will. This results in large heat losses in spite of the complex insulation often lead to the fact that pyrolysis processes can no longer be carried out autothermally. The transport in the longitudinal direction is generally made by inclining the rotary cylinder achieved.

As a result of this inclination, the drum becomes helical as it rotates Longitudinal transport of the drum good forced. The residence time is therefore given by existing other dimensions essentially from the speed and the length of the drum. In order to obtain sufficiently long dwell times, the drum must therefore accordingly be long and driven with a low drum speed. The dwell time can also be achieved by corresponding downtimes. These demands after low speed or

However, the introduction of downtimes is very disadvantageous for the process, because on the one hand they only bring about a small amount of 'good redeployment', on the other hand the risk of caking, especially if the drum is expected to come to a standstill grows big.

In order to avoid these disadvantages described, therefore, according to the invention proposed to move the rotary drum preferably horizontally and additionally preferably to equip with a spiral conveyor on the inside of the Drum is arranged. This ensures that the direction of transport is in contrast to the inclined drum depends on the direction of rotation of the drum. The material movement can therefore advance and periodically change the direction of rotation according to the invention can be controlled backwards.

The material can be moved through the drum in a pilgrimage step, whereby the movement by appropriate choice of the clockwise and counterclockwise rotation components of the Rotational movement can be arbitrarily high without a corresponding at the same time high longitudinal speed occurs in one direction alone.

The dwell time depends on the length of the drum and the speed of rotation Drum independent. So it can be used relatively small drums with a short length will.

In addition to the cost savings for the otherwise usual large drum dimensions the heat loss is of course demonstrably smaller. Furthermore, by the pilgrim's step movement a good rearrangement and mixing of the pyrolysis material can be achieved.

Likewise, the risk of caking is constant because of the large, possible ones reversing wall speed of the drum is almost impossible.

In combination with the inner radiant tube heating, there is a risk of caking on the outer drum is also reduced, and the outer drum can be adjusted as required Of course, you can also experience additional heating.

Claims

Claims (1)

Claims with claim 1 rotary kiln for a pyrolysis process indirect heating characterized in that the heating by a central arranged inner jet pipe (2) takes place. Claim 2 rotary kiln according to claim 1, characterized in that the inner tube (2) is preferably firmly connected to the drum. Claim 3 rotary kiln according to claims 1 and 2, characterized in that that the inner jet pipe (2) is preferably rotatably mounted in the drum. Claim 4 rotary kiln according to claims 1 to 3, characterized in that that the jet pipe (2) is provided with an internal flue gas circulation (4). Claim 5 rotary kiln according to claims 1 to 4, characterized in that that the flue gas circulation is generated by an injection pipe. Claim 6 rotary kiln according to claims 1 to 5, characterized in that that the material movement with a horizontal drum position by preferably helical Built-in is enforced. Claim 7 rotary kiln according to claims 1 to 6, characterized in that that the drum is driven alternately clockwise and counterclockwise. Claim 8 rotary kiln according to claims 1 to 7, characterized in that that the ratio of the clockwise motion components to the counterclockwise motion component can be changed for the purpose of changing the resulting longitudinal movement. Claim 9 rotary kiln according to claims 1 to 8, characterized in that that the size of the clockwise or counterclockwise rotating part to change the mixing and loosening movement is variable. Claim 10 rotary kiln according to claims 1 to 9, characterized in that that the material discharge preferably via a fixed discharge hood (9), which encloses the discharge end of the rotary drum by an annular labyrinth (11), is made. Claim 11 rotary kiln according to claims 1 to 10, characterized in that that the rotary drum at the entry end preferably with a lockable entry slide is provided.