WO1999060320A2 - Coke-heated circulating gas cupola furnace for material and/or energetic recycling of waste materials having different compositions - Google Patents

Abstract

The invention relates to an additional embodiment for the arrangement of a lower annular suction and gas relaxation chamber (12) on a coke-heated circulating gas cupola furnace for material and/or energetic recycling of waste materials having different composition as described in main patent P 196 40 497, in which suctioning of gaseous organic matter which has been completely broken down into its basic components CO, H2, H2O and CO2 and into its trace components or has been already reformed is not yet reliably prevented. According to the invention, the lower annular suctioning and gas relaxation chamber (12) is arranged below the melting and overheating zone which extends up to the plane formed by the position of the jet gas compressor (24). Said arrangement makes it possible to draw off the excess gas directly from the furnace shaft from the melting and overheating zone at high temperatures of around 2,000 °C. The excess gas is also guided through the burning coke layer of the melting and overheating zone of the coke-heated circulating gas cupola furnace. CO2 is converted to CO by lowering the temperature of the gas as a result of energy-consuming Boudard equilibrium reaction. Fluidic separation of the excess gas from process gas is simultaneously carried out.

Description

 Description Coke-heated cycle gas cupola furnace for material and / or energy recovery of waste materials of different compositions

The invention relates to a coke-heated cycle gas cupola furnace for the material and / or energetic utilization of waste materials of different compositions according to main patent P 196 40 497. The flue shaft of the cycle gas cupola, which is flared from the loading hopper to the stove and consists of flared and / or cylindrical furnace sections, has in the area of the cycle gas and excess gas extraction level, there is a large-volume suction and gas calming ring chamber, which are connected by a furnace shaft part with a narrowing in cross-section and with a built-in oxygen direct injection lance directed obliquely to the melting and superheating zone. An additional gas vent is located below the hopper and a pipe socket for a viewing hole or for the installation of an additional burner is installed in the upper suction and gas calming ring chamber. The lower suction and gas calming ring chamber is directly connected to a solids supply lock, as well as an excess gas suction connection and one or more water supply devices. This arrangement and design of the individual furnace sections is intended to ensure an undisturbed process flow in the material and / or energy recovery of different feedstocks with different consistency and different softening intervals, in which on the one hand the gas velocities in the area of the two gas extraction levels and thus the clogging and dust deposits in the area of the Circulation gas and excess gas suction openings are reduced to such an extent that the unimpeded process flow even when using moist feed materials, such as domestic waste fractions, is guaranteed and process-specific temperatures of high 800 ° C no longer lead to harmful sintering phenomena. In addition, the local narrowing of the furnace shaft above the excess gas extraction level in the area of the oxygen nozzles enables the formation of a second, thermo-chemically active zone characterized by controllable oxygen supply and a longer residence time of the feed materials, thereby ensuring the controlled completion of all material-specific gasification and degassing processes of the feed materials can be realized before the fill further sinks. The cycle gas cupola furnace shown in the main patent P 196 40 497 can be used advantageously for the material and / or energetic utilization of waste materials of different compositions, but can be arranged by arranging the lower suction and gas calming ring chamber above the melt formed by the gas jet compressor. and overheating zone sometimes do not prevent that their basic components CO, H ₂ , H ₂ 0, C0 ₂ and m their trace components have not yet been completely broken down or gaseous organics which have already been re-formed are sucked off again. Additional analytical monitoring systems for the extracted excess gas were therefore necessary for the technological process control. The present invention relates to a further embodiment of the arrangement of the lower suction and gas calming ring chamber on a coke-heated cycle gas cupola for the material and / or energy recovery of waste materials of different compositions according to main patent P 196 40 497, which do not yet completely cover the suction its basic constituents CO, H ₂ , H ₂ 0, C0 ₂ as well as gaseous organics broken down into their trace components or already re-formed are reliably prevented.

This is achieved by placing the lower suction and gas calming ring chamber below to the level of the melting and superheating zone formed by the position of the gas jet compressors. This arrangement has the effect that the Gun gas is withdrawn directly from the melting and superheating zone at high temperatures around 2000 ° C from the furnace shaft. The excess gas is also passed through the glowing coke layer of the melting and superheating zone of the coke-heated cycle gas cupola. Due to the energy-consuming effect of the Boudouard balance, C0 _{2 is} converted to CO while lowering the gas temperature. At the same time, the excess gas is split off from the process gas in terms of flow technology. It is also advantageous that the furnace shaft, which is flared from the loading hopper to the hearth, from the level of the melting and superheating zone down to the hearth area provides an increasing coke volume for the Bouαouard reaction and thus ensures a higher effectiveness of this desired reduction reaction. In metallurgical terms, an improvement in the reduction conditions compared to the oxides of the molten phases from the material and / or energy recovery of waste materials of different compositions is achieved, which in turn results in better metal and slag qualities.

The arrangement according to the invention of the lower suction and gas calming ring chamber on a coke-heated cycle gas cupola furnace for the material and / or energy recovery of waste materials of different compositions will be explained in more detail using an exemplary embodiment. The accompanying drawing shows a longitudinal section through the coke-heated cycle gas cupola from the cycle gas level to the stove. It shows that below the charging funnel 1 begins a downwardly conically widened furnace shaft part 4, m the gas supply nozzles 3, which are inclined downward above the cycle gas suction plane 2 and are connected to the clean gas side of a gas industry (not shown) or a separate gas reservoir, are arranged. In the cycle gas suction level 2 there is a large-volume suction and gas calming ring chamber 5 which widens conically at the top available, which is delivered with the refractory material 10 and is coupled with a water cooling 6 for start-up and shutdown processes. This suction and gas calming chamber 5, which also has a pipe socket 7 for the installation of an additional burner and / or a viewing hole, and one or more cycle gas suction socket 8 with inspection opening 25, which are provided via pipes with integrated actuators, measuring devices for determining volume flow and compensation elements for pipe expansions , is connected directly to an oxygen-operated, water-cooled gas jet compressor 24. Immediately below the suction and gas calming ring chamber 5 is a cylindrical furnace shaft part 9, which is provided with the refractory material 10 to n in the area of the excess gas suction plane 11, and has one or more built-in oxygen lance 13 directed obliquely to the melting and superheating zone . The furnace shaft part 9 is connected at the bottom in the region of the excess gas suction level 11 with a large-volume suction and gas calming ring chamber 12. In the ring chamber 12 or alternatively in the excess gas suction nozzle 14 there is a water supply device 15 and above the water supply device 15 a supply lock for solids 16 with two gas-tight locking devices 17; 18 and a thrower 19 installed. The excess gas suction connection 14 is connected via a delivery element, not shown, to a gas industry, also not shown, which in turn is optionally connected to the gas supply nozzles 3 on the clean gas side. At the level of the excess gas suction connection 14 of the annular chamber 12, the gas jet compressor 24 merges and the furnace shaft 20 continues as a truncated cone that widens conically downwards and merges below the annular chamber 12 m with a cylindrically shaped and supplied hearth 21 in which the exhaust openings for the molten metal 22 and liquid slags 23 are installed. For the material and energy recovery of a mixture of a household waste fraction, bulky waste and so-called stabilizer of organic origin, the procedure described below is to be followed. The genus consists of 26.7% shredded domestic garbage (I), 31.6% bulky garbage with one

Scrap fraction (II), 18.9% domestic garbage stabilizer (111/20 - 60 mm), 17.2% household garbage stabilizer (IV / 0 - 20 mm), 3.8% coke (V) and 1.8% limestone (VI) as a slag generator. The main composition of the substances is shown in Tables la to lc.

The set weight is 1000 kg. The furnace is equipped with 6 circulating gas emitters and has a capacity of 7.50 t / h feed materials. It is prepared like a coke-fired oven. After the full coke has been introduced, the furnace is closed and burned with an auxiliary burner and natural draft with the flap closed in the circulating gas and excess gas line over the emergency chimney. After the full coke column has burned through, it is blown down to white heat using oxygen and air. The air opening on the gas jet compressor 24 is closed and the flaps m of the cycle gas and

Excess gas line opened. Immediately afterwards, the process begins with the abandonment of the first and further sentences until the upper level is reached. All subsequent records are time-dependent as a function of the gasification, combustion and melting capacity, that is, depending on the rate of descent of the fill. The gas jet compressors 24 are operated with a total of 2164 Nm ³ / h of oxygen, so that more than 100% gas at the cycle gas suction level 2, ie the 3750 Nm ³ / h of cycle gas present here plus the sealing gas quantity of 52 Nm ³ / h, the over the loading hopper 1 is introduced, withdrawn and m the melting and combustion zone are blown. Alternatively, a gas vent 27 is provided above the sealing gas supply for the evaporation products that arise when a sealing gas of higher temperature is used, which is connected to the gas industry and through which these evaporation products directly Gas industry can be supplied. Since the processes in the furnace are temperature-dependent, approx. 50% of the amount of process gas generated in the conical shaft 26 between the excess gas suction level 11 and the circulating gas suction level 2 and the rest through the combustion and thermochemical material conversions in the melting and superheating zone, ie primarily through combustion of the solid carbon potential educated. 8693 Nm ³ / h are withdrawn as excess gas and fed to the gas industry, which includes a disintegrator. The temperature of the gas is 550 ° C. The gas leaving the disintegrator at approx. 35 ° C consists of approx. 36% H ₂ , 4.6% N ₂ , 15.3% C0 ₂ , 42% CO and 3.1% H ₂ 0. About 359 1 / h of water condense out. Furthermore, approx. 800 kg / h molten metal and 1660 kg / h slag, which meet the requirements of use as a building material. After gas cleaning, there is a purified fuel gas with an energy equivalent of 19.48 MW. In addition, approx. 40 kg / h disintegrator sludge and 0.8 kg / h loaded activated coke. These substances are added to the system internally as external dust addition by the gas jet compressor 24 or briquetted via the charging hopper 1, slagged and used for energy. The water cooling 6 can be used in normal operation as a preheating of the input materials. The function is used as cooling during start-up and shutdown. Table la

Elemental analysis [mass%]

Fabric Fe C S Cu Cd Ni AI

Hg Pb Cr As Zn

I 3.62 36.21 0.66 0.07 0.01 0.01 0.53

0.00067 0.13 0.03 0.00001 0.20

II 22.98 34.41 0.21 0.02 0.01 0.01 0.18

0.00067 0.04 0.01 0.00001 0.06

III 3.62 36.21 0.66 0.07 0.01 0.01 0.53

0.00067 0.13 0.03 0.00001 0.20 IV 2.53 25.28 0.46 0.05 0.01 0.01 0.37

0.00 0.09 0.02 0.00 0.14

V 90 1

VI

Table lb gaseous fractions [mass%]

Substance H ₂ 0 ₂ N ₂ C0 ₂ Cl ₂ H ₂ 0

I 4.60 24.48 0.40 0.66 15

II 4.21 27.65 0.26 0.21 10

III 4.60 24.48 0.40 0.66 15

IV 3.21 17.09 0.28 0.46 15

V

VI 50

Table lc mineral components [mass

Substance Si0 ₂ A1 ₂ 0 ₃ CaO MgO Fe ₂ 0 ₃ FeO MnO K ₂ 0

I 14.7 4.53 4.13 0. 6 2.00 0.40

II 5.10 1.52 1.53 0.20 0.70 III 14.7 4.53 4.13 0.6 2.00 0.40

IV 25.9 8.0 7.3 1.1 3.5 0.7

V 3.79 2.48 1.13 0.05 0.75 0.75 0.08

VI 50.00 Reference list

Begichtungstrichter Kreislaufgasabsaugebene Gaszufuhrungsduse conically flared furnace shaft part large volume suction and gas calming annular chamber water cooling pipe socket Kreislaufgasabsaugstutzen furnace shaft part with a local narrowing refractory Uberschußgasabsaugebene large volume suction and gas calming annular chamber oxygen direct-injection lance Uberschußgasabsaugstutzen Wasserzufuhrungseinrichtung solid delivery sheath shutter closure device funnel-shaped Einwurfoffnung frusto-conical part of the furnace hearth Abzugsoffnung molten metal Schlackeabzugsoffnung gas jet compressor Revisionsoffnung conical furnace shaft gas vent

Claims

 Claim Coke-heated cycle gas cupola for material and / or energy recovery of waste materials of different compositions according to patent application P 196 40 497, consisting of a vertical furnace shaft, which is flared from the hopper to the stove, with several furnace gas suction openings arranged around the circumference of the furnace shaft, below the coating, through channels with nozzles installed above the stove in the area of the melting and superheating zone, which have centrally guided oxygen lances and act like a gas jet compressor, the furnace shaft in the area of the cycle gas and excess gas extraction level each has a large-volume suction and gas calming chamber, which through a furnace shaft part with a cross-sectional constriction and with a built-in oxygen direct injection lance directed obliquely to the melting and overheating zone are connected and immediately below the hopper n additional gas discharge is arranged, characterized in that the excess gas extraction level (11) and the large-volume suction and gas calming chamber (12) are arranged below to the level of the melting and superheating zone formed by the position of the gas jet compressors (24).