DE4041744C2 - Explosive combustion reactor - Google Patents

Description

The invention relates to a reactor for the combustion of explosives the preamble of claim 1.

Explosives are solid, plastic or liquid explosive substances, such as Explosives, fuels, guns, igniters, igniters and pyrotechnic Fabrics.

Explosive items are items that contain explosives and an explosive, shooting or propelling, ignition, ignition effect or pyrotechnic effect. To the explosive objects belongs to ammunition, for example.

Under the above term "combustion" any oxidative reaction is meant be understood that the explosive with the contained in the explosive or additional oxygen (also air-oxygen) after ignition with of an open flame and which leads to the explosive Explosiveness loses.  

DE 38 22 648 A1 describes a reactor for the combustion of explosives known who has a series of cassettes for the goods to be burned, which are fed lengthways through the reactor. He has burners to ignite of the estate, an inlet for combustion gases and a gas discharge nozzle on. This device forms the preamble of claim 1. The reactor has the character of an open fire place, that is, the exhaust gases Rapidly deflagrating burns can escape outdoors unhindered.

From US 4 136 624 is a furnace for incinerating industrial waste, such as e.g. B. of paint sludge or resin residues in containers known. To teach, there are no guidelines on how to destroy explosives in an environmentally friendly manner.

From DE-OS 22 27 266 an oven for firing ceramics is known. Lessons on environmentally friendly combustion of explosives are not given.  

The object of the invention is to create a reactor the combustion with the least possible combustion gas removal with high operational safety and while avoiding uncontrolled delivery of Combustion gases to the environment.

According to the invention, this object is achieved by the reactor with the features of claim 1 the invention are the subject of dependent claims.

The invention is explained in more detail with reference to two figures.

Fig. 1 shows a longitudinal section through a reactor,

Fig. 2 shows a cross section.

The reactor according to the invention consists, for. B. from a cylindrical, stationary housing 1 made of steel or cast steel, which has at least three structurally identical reaction zones. With this housing 1 tightly connected, in this embodiment, cylindrical cooling zones 1 a follow on both end faces, which can be cooled from the outside with liquid or gaseous coolant or by heat radiation.

Between the housing 1 and the cooling zones 1 a, a thick-walled intermediate wall 1 b is provided here, which has a passage opening through which the material can enter the first reaction zone or leave the last reaction zone. The intermediate wall 1 b serves as radiation and splinter protection. Lock chambers 2 are connected to the cooling zones 1 a on the inlet and outlet sides. These seal the reactor gas-tight with a slide 3 and to the outside with a flap (not shown).

The material to be treated 14 is here in expediently rectangular cassettes 6 which are open at the top and form a form-fitting but not connected row through the entire reactor. One or more unfilled cassettes 6 can be arranged between two filled cassettes 6 . The housing walls of the entire reactor (sluice 2 , cooling zone 1 a, reaction zones, cooling zone 1 a, sluice 2 ) are preferably designed in the lower inner area in such a way that the correspondingly designed cassettes 6 are moved (pushed) one behind the other, without gaps and in a form-fitting manner, through the reactor. can be.

The pushing movement takes place by means of suitable devices 12 from the entrance lock in cycle times, corresponding to the required dwell times of the material in the reactor.

Further installations along the inner housing wall (e.g. the inclined side walls 15 shown in FIG. 2 projecting beyond the edges of the cassette) prevent parts of the goods from falling under the cassettes 6 . There is a rupture disc 10 on the reactor which, when a permissible maximum pressure (eg an overpressure of 0.3 bar) is exceeded, releases the overpressure and thus protects the reactor from damage. An ejection device is drawn with the reference number 11 .

Each reaction zone (five reaction zones are shown in FIG. 1) has a pilot burner 5 which can be set up from the outside by means of a suitable device so that the flame clearly touches the material to be treated. The pilot burner 5 is preferably operated with fuel gas and air or oxygen. If the burner 5 is not required in a reaction zone, it can be withdrawn or removed entirely by means of the device mentioned. The pilot burner 5 can, for. B. by varying the pressures of the gases supplied, in their flame pattern (geometry) and / or in their ignition energy to the respective explosives.

Each reaction zone also has at least one gas supply nozzle 9 and at least one gas discharge nozzle 8 - however, only the nozzles 8 and 9 of three reaction zones are shown. The connectors 8 and 9 are preferably arranged on the housing wall in such a way that a targeted atmosphere control, preferably transverse to the main axis of the reactor, is achieved.

Oxygen or combustion air additionally required for combustion in some cases can be fed to each reaction zone through lances 4 , which are arranged in such a way that the oxidizing agent strikes where the combustion takes place. Oxygen or air to support the combustion can also be added or, alternatively, added to the circulating reaction gas partial stream and then fed to the reactor via the gas feed pipe 9 .

Pipes (not shown) are connected to the sockets 8 and 9 and each lead to a manifold via motor-controlled control flaps. In this version, each reaction zone is equipped with a flexible, gas-permeable splinterguard (here, for example, the armored chain curtain 7 ) in such a way that free-flying burning parts do not get into explosive-containing but not burning cassettes 6 .

Fig. 2 shows a cross section through a reaction space. It can be seen the circular structure of the housing 1 , the arrangement of the gas supply connector 9 and the gas discharge connector 8 so that a cross flow occurs. The cassette 6 with the material 14 to be burned is located in the lower part of the reactor. The burner 5 and the lance 4 for supplying oxygen are shown here on the right edge. The burner can be moved up and down. Its flame must be able to touch the combustion material 14 . The housing 1 is designed in its central region (side wall 15 ) so that any solids escaping from the cassette 6 fall back into the cassettes 6 through the projections and the sloping side wall parts.

The cassettes 6 can be formed symmetrically to the longitudinal axis of the furnace or can be provided with a device from which the added oxidation medium (from FIG. 4 ) is conducted into or below the combustion material 14 . For this, e.g. B. a wall 16 (a grate) or a corresponding element that guides the inflowing gas into the combustion material 14 may be provided.

Claims (7)

1. Reactor for the combustion of explosives, in the form of a push-through reactor, with a series of cassettes ( 6 ) for the material to be burned ( 14 ), which are guided lengthwise through the reactor, with burners ( 5 ) for igniting the material ( 14 ) , Combustion gas inlet and gas discharge nozzle ( 8 ), characterized in that

• - That at least three reaction zones are provided, each containing a burner ( 5 ), a gas supply nozzle ( 9 ) and a gas discharge nozzle ( 8 ),
• - That the reaction spaces are sealed to avoid uncontrolled release of combustion gases to the environment and
• - That a burst protection ( 10 ) is provided for releasing an impermissible excess pressure.

2. Reactor according to claim 1, characterized by lances ( 4 ) for supplying an oxidizing agent in at least one of the reaction zones. 3. Reactor according to claim 1 or claim 2, characterized by cooling zones ( 1 a) before and after the reaction zones. 4. Reactor according to one of the preceding claims, characterized by partitions ( 1 b), gas-tight lock chambers ( 2 ) and slide ( 3 ) for sealing the reaction space to the outside. 5. Reactor according to one of the preceding claims, characterized in that the gas flow (the gas flow between gas inlet 9 and gas outlet 8 ) extends transversely to the main furnace axis in each reaction space. 6. Reactor according to one of the preceding claims, characterized by a flexible splinterguard (armored chain curtain 7 ) between the reaction zones. 7. Reactor according to one of the preceding claims, characterized by cassettes ( 6 ) which are open at the top, rectangular and form-fitting and can be joined together to form a continuous row.