DE3317701C2 - A method of operating a vertical shaft moving bed reduction reactor for reducing iron ore to sponge iron - Google Patents

Abstract

Process for operating a vertical moving bed reduction reactor for reducing iron ore to sponge iron with a reduction zone in the upper part of the reactor and a cooling zone in the lower part of the reactor, in which the desired degree of metallization of the reducing ore in the reduction zone and the desired degree of Cementation is obtained in the cooling zone, the method being characterized in that a predetermined flow of a reducing gas composed of carbon monoxide and hydrogen is fed into the reactor and in that the ratio of the reducing gas flow in the reduction zone to the reducing gas flow in the cooling zone is adjusted so that at least the The metallization taking place in the reduction zone and the cementing taking place in the cooling zone are changed, the carbon dioxide concentration in the reduction zone being adjusted to a value at which the desired degree of metallization is achieved there and at which the carbon dioxide content is achieved in the cooling zone to a value at which the desired degree of cementation in the cooling zone is obtained.

Description

The invention relates to a method for operating a moving bed reduction reactor with a vertical Manhole for reducing iron ore to sponge iron, in which a product with a predetermined Degree of metallization and carburization is maintained.

Typically the manufacture of sponge iron carried out in a moving bed reactor with vertical chess and in two main stages: namely the reduction of the ore in a reduction zone through which a suitable hot reducing gas is passed through mainly composed of carbon monoxide and hydrogen, passed at a temperature in the range of 700 to 1000 ° C and preferably 750 to 950 ° C is, and the cooling of the reduced sponge iron in a cooling zone through which a gaseous coolant at a temperature below about 200 ° C and

ίο is preferably passed below 100 ° C. Systems of this general type are described in US-PS 37 65 872, 38 16 102 and 42 16 011, in which a vertical Reactor used with a reduction zone in the upper part and a cooling zone in the lower part will. The ore to be treated is fed into the top of the reactor and down there through the reduction zone allowed to flow where it is reduced by hot reducing gas and then the reduced flows Ore down into the cooling zone, where it is made by contact with a stream of a suitable cooling gas is cooled and cemented. The cooled sponge iron is then removed from the bottom of the reactor. Typically, both the reducing gas and the cooling gas are circulated, if desired in closed loops, to which streams of fresh (so-called make-up) reducing gas are added and from which streams of used gas are withdrawn.

In a number of known direct reduction processes, the reducing gas required to reduce the iron is used in a catalytic reforming unit by converting natural gas according to the following Equations generated:

CH ₄ + H ₂ O-CO + 3H ₂
CH ₄ + CO ₂ --2 CO + 2 H ₂

In the reforming reactions of natural gas, which is mainly composed of methane, this is in hydrogen and carbon monoxide in the presence of an oxidizing agent of either water or carbon dioxide converted. As a result, a reforming gas is obtained, which is essentially composed of hydrogen and Composed of carbon monoxide. More recently it is due to the decrease in availability and the increase Natural gas costs have become extremely important and desirable for a direct reduction process the required amount of natural gas too

so minimize.

The reducing gas introduced into the reducing zone of the reactor is typically at a higher temperature and contacts the downward flowing iron ore, thereby reducing the iron oxide contained therein according to the following Basic reactions are reduced:

3 Fe ₂ O ₃ + H ₂ / CO —2 Fe ₃ O ₄ + H ₂ O / CO ₂ (3) Fe ₃ O ₄ + H ₂ / CO —3 FeO + H ₂ O / CO ₂ (4)

FeO + H ₂ / CO -Fe + H ₂ O / CO (5)

The used reducing gas leaving the reactor is cooled in order to reduce the Iron ore to remove water formed with hydrogen and then the dehydrated exhaust gas into the The reactor's reduction zone is recirculated. The recirculation or recycling of the exhaust gas can be done on different

can be done in different ways: For example, you can lead the gas directly back into the reactor or you can The gas first pass through the reformer and a heating device or you can just pass the gas through cycle the heater. In any case, however, fresh reducing gas is added to the im Circulated exhaust gas before this is introduced into the reactor. As the amount of during The carbon dioxide formed in the reactor during the reduction process must be a part of that which is consumed Gas can be vented or purified to a suitable overall carbon balance within the reduction zone to maintain.

As previously mentioned, the fresh reducing gas, which is typically generated by the catalytic conversion of methane in the natural gas fed into the process, represents the net carbon addition to the process due to the carbon content of the natural gas. In order to be able to carry out the reduction process under constant conditions and continuously , it is necessary to remove the carbon from the system in an amount substantially equivalent to the net amount of the supplied amount of carbon. Carbon can be removed from the system in a combined form with the sponge iron in the form of iron carbide or in gaseous form as CO, CO ₂ and CH4, which is vented from the loop in the form of used gas.

A proper balance between the amount entering and exiting the process Carbon is required to cause too much carbon to deposit on the sponge iron that is moving through the reactor to avoid. It is true that carbon can be effectively eliminated from the process, by venting at least some of the off-gas from the reactor, however, this method works the hydrogen, which is also present in the exhaust gas and which is particularly effective in the reduction, is also lost.

DE-OS 30 23 121 discloses a method for the gaseous reduction of iron ore to sponge iron known, in which a predetermined desired degree of carburization is achieved.

The present invention proceeds from the prior art according to DE-OS 30 23 121, in which the iron ore is reduced in a reduction zone by flowing the reducing gas at a temperature of 700-1100 ⁰ C and in a cooling zone in the lower part of the reactor a temperature below 200 ⁰ C is cooled and carburized. The reduction zone forms part of a gas flow loop through which the reducing gas is returned to the reduction zone and in which the circulated gas is passed through a cooler, a carbon dioxide removal unit and a heating device, the cooling zone forming part of the cooling gas loop through which the Ga cooled outside the reactor? is returned in the circuit to the cooling zone. A predetermined stream of fresh reducing gas composed primarily of hydrogen and carbon monoxide is introduced into the system as a first stream, and this first stream is converted into a second stream, which is introduced into the reducing gas loop, and a third stream, which is introduced into the cooling gas loop, divided.

The object of the invention is, in a method of the aforementioned type for producing a product with a predetermined degree of metallization and carburization to minimize the need for natural gas and to optimize the total energy demand.

This object is achieved according to claim 1 by the flow rate of the first Current holds essentially constant and the splitting ratio of the second to the third stream so modified that thereby the interrelated reduction and carburization reactions in the respective reduction and cooling zones are effected, and a product with a predetermined Degree of metallization and carburization is maintained.

For a better understanding of the invention it is shown that the reduction of FeO in the reduction zone of the reactor through a conversion of the hot reducing gas, which is mainly made up of carbon monoxide and hydrogen is composed as follows:

CO + FeO -Fe + CO ₂
H ₂ + FeO -Fe + H ₂ O

The carburization reactions that take place in the reactor at the same time as the reduction reactions can occur can be expressed by the following equations:

2 CO-C + CO ₂
3C + Fe-FeC ₃

It is known that the above cancellation reactions are favored at temperatures ranging from about 500 to 700 ⁰ C and in that the carbon deposition takes place on the sponge iron, therefore, a much greater extent in the cooling zone of the reactor. From equation (8) it becomes clear that the carburization rate in the reduction zone and in the cooling zone depends to a large extent on the concentration of CO contained in the reducing or cooling gas. In the same way it can be seen from equation (6) that the reduction rate is determined to a considerable extent by the concentration of CO in the reducing gas.

It is known to produce carbon from the reduction process to get the desired overall carbon balance by having at least one Part of the used cycle gas is vented. The present invention provides an alternative approach selective elimination of carbon from the reduction system available by controlling Carbon dioxide is adsorbed from the spent gas circulating in the reactor. By adsorption of carbon dioxide from the cycle gas, the required amount of carbon can be eliminated, without there being any loss of hydrogen in the system. As a result, you need less natural gas to compensate for the loss of reducing capacity in the cycle gas compared to the known ones Add to systems that clean or vent a significant portion of the cycle gas.

Preferably, substantially all of the carbon dioxide is derived from the circulating reducing gas removed before the circulating reducing gas is returned to the reduction zone.

For the production of a sponge iron with a metallization of at least 94% and a carbon content of less than 1.0%, it is advantageous to have substantially all of the amount in the reactor

fresh reducing gas supplied into the reducing gas loop is introduced.

It is also advantageous to produce a sponge iron with a metallization of 80 to 84% and a carbon content of 2.7 to 3.2% if you take most of the fresh reducing gas introduces into the cooling loop.

F i g. 1 is a diagram of a system with a moving bed reactor with a vertical shaft according to a preferred embodiment of the invention Procedure,

F i g. Figure 2 shows a graph in which the percentage of metallization as a function of the relative gas flow is shown in the reduction and cooling zones,

F i g. 3 shows a graph for the percentage of carbon on the sponge iron, d. n. the carburization, as a function of the relative gas flow into the reduction zones and cooling zones, and

F i g. 4 shows a graph for the total percentage of carbon absorbed in the form of CO2 as Function of the relative gas flow in the reduction and cooling zones.

Referring to FIG. 1, a catalytic reforming unit 80 of known type is supplied with natural gas through line 78 and with steam injected through line 79. The steam is generated from water introduced through line 85 into a waste heat furnace 84 through the coils of line 79 into duct 81 . The natural gas and vapor mixture are preheated by passing them through coils in the duct portion 81 of the reformer 80 , whereupon it is passed through a heated catalyst bed in the lower portion 82 of the reformer where it is converted into a gas mixture consisting primarily of carbon monoxide , Hydrogen and water vapor. The reformed gas exits the reformer 80 through a line 83 and enters a quench cooler 90 where the gas is cooled and dewatered. Upon exiting the cooler 90, the gas flows through a conduit 92 having a flow rate actuator 94 at a flow rate referred to as F ₀ . The gas stream Fo splits into two separate streams, namely Fi, which flows through line 95 and is used as make-up reducing gas in the reduction loop, and Fa, which flows through line% and is used as make-up cooling gas in the cooling loop.

With particular reference to the reduction loop as shown in FIG. 1, the gas stream Fi flows through a conduit 95 provided with a flow rate actuator 97 and is combined with the spent gas from the reactor which is returned to the reduction zone and which is designated as F3 to form a reducing gas stream F2, which flows through a conduit 98 into a heater 100 wherein the gas is heated in a known manner to a temperature in the range 700-1100 ⁰ C, preferably about 900 ° C. The heated reducing gas leaves the heater 100 through a line 101 and enters the reduction zone 12 of the reactor designated 10. The reducing gas entering the reducing zone 12 of the reactor 10 is allowed to flow upward therein in contact with the descending iron ore to thereby effect the reduction of the iron ore contained therein. The used reducing gas leaves the reactor 10 through a line 18 and enters the cooler 20 , where it is cooled and dewatered. The cooled and dewatered spent gas leaves the cooler 20 through a line 21, with a portion of the gas designated Fe being vented or transported to a storage room through lines 22, 27 equipped with a flow rate actuator 24 . The gas flow denoted by F% can also be used as fuel in the reformer 80 or in the heater 100 .

The greater part of the spent gas from the reactor flows through a line 25 into the suction side of the compressor 26. The compressed suction side of the compressor 26. The compressed used gas leaves the compressor 26 through a line 28 and flows into a carbon dioxide adsorption unit 30, wherein the carbon dioxide contained in the used gas is removed. After the carbon dioxide has been removed from the spent gas, the gas stream designated F3 flows through a conduit 32 which is provided with a flow rate actuator 34 and is combined with the gas stream F, as previously indicated

As mentioned, part of the gas flow Fo can flow through a line 96 into the cooling loop of the reduction system as supplementary cooling gas. The supplemental cooling gas F4 flows through a line 96 which is provided with a flow control element 98 'and combines with the cooling gas which is circulated in the cooling loop of the reactor 10 to form a cooling gas flow labeled Fs. Gas streams F ₅ flow through a line 99 and are introduced into the cooling zone 14 of the reactor 10. The cooling gas is allowed to come into contact with the descending reduced sponge iron through the cooling zone in order to cool and cement the floating iron contained therein. The cooling gas leaves the cooling zone 14 through a line 103 and enters a cooler 110 where it is cooled and dewatered. The cooled and dewatered gas stream flows through line 112 into the suction side of compressor 116, where it is pumped back into cooling zone 14 through line 118 after being combined with stream F4 to form stream Fs .

It remains to be noted that in the cooling zone the in F i g. 1 described embodiment no external Cleaning is needed.

Part of the make-up stream F4 is consumed by the reduction and carburization reactions of the aforementioned type that take place in the cooling zone 14, while the remaining part of the make-up cooling gas introduced into the cooling zone 14 flows into the reduction zone 12 within the reactor 10 by the adsorption of carbon dioxide In the used cycle gas, carbon can be selectively removed from the system without the other reducing components being lost and the amount of natural gas to be fed to the process is thereby minimized. In practical operation, the gas flows F ₀ , F2 and F5 are preferably kept at a constant value, because these flows determine the optimal design of the reforming unit, the heating unit and the cooling loop compressor. A typical gas composition of the stream Fo is as follows:

H ₂ 73.0 CO 14.2 CO ₂ 8.5 CH ₄ 3.5 H ₂ O 0.5 N ₂ 0.3

The carbon monoxide contained in the stream Fo is used as a reducing agent according to equations (3), (4) and (5) or as a carburizing agent according to equation (8). In the direct reduction of sponge iron, carbon monoxide tends to reduce iron oxide at higher temperatures, while there is a tendency for carbon to deposit on the sponge product at lower temperatures. In order to control both the metallization and the carbon content of the sponge iron product in order to achieve a "faded" product with either a higher metallization and a lower carburization or a lower metallization and a higher carburization, the relative amounts of the make-up gas flow F4 to the cooling loop and Controlled variably from Fi to the reduction loop. In other words, by keeping the gas flows Fo, Fi and F5 constant and by varying the gas flow ratio F4 / F0, a balanced sponge iron product is obtained.

Fig.2 shows the effect of the metallization of Sponge iron as a function of the change in the F4 / Fo ratio.

In the same way, FIG. 3 shows the effect on the percentage carbon content of the sponge iron product as a function of the Fi / Fo ratio. It is clear from Figures 2 and 3 that when the F4 / F0 ratio approaches zero, a product with very high metallization and low carbon content is obtained, while when the F4 / F0 ratio approaches 1.0 approaches, a lower metallization and a higher carbon content can be obtained. In order to use the important effect which the change in the FaI Fo ratio has on the metallization and carburization of the sponge iron product, the carbon dioxide content in the stream F3 should be approximately zero. In order to achieve the desired control of the reduction and carburization reactions which take place in the reduction and cooling zones, little or no carbon dioxide should be present in the reducing or cooling gas fed to the reactor.

F i g. Fig. 4 shows the relationship between the percentage of carbon adsorbed as carbon dioxide, calculated on the basis of the total carbon entering the system as natural gas, as a function of the F4 / Fo flow ratio. The curve in Figure 4 clearly shows that as the Ft / Fo ratio approaches zero, about 80% of the carbon introduced into the system is removed as carbon dioxide in the adsorber. This indicates that the amount of carbon in the product is relatively low. When the F4 / Fo ratio approaches 1.0, then about 62% of the carbon introduced into the system is removed as carbon dioxide, with the remainder being removed as carbon on the system Sponge iron is deposited. In either case, the overall carbon balance in the system is properly maintained without the need to vent large amounts of gas, thereby increasing the overall efficiency of the reduction process.

For this purpose 3 sheets of drawings

Claims (4)

Patent claims: 1. Method of operating a moving bed reduction reactor with a vertical shaft for reducing iron ore to sponge iron, with a reduction zone 12 in the upper part, in which the Iron ore reduced by reducing gas flowing through it at a temperature of 700 to 1100 ° C is, and a cooling zone 14 in the lower part of the reactor, in which the reduced iron ore on a Temperature below 200 ° C is cooled and carburized, the reduction zone being part of a Forms gas flow loop through which the reducing gas is returned to the reduction zone, and in which the circulated gas is passed through a cooler, a carbon dioxide removal unit and a heating device is guided, wherein the cooling zone forms part of the cooling gas loop, through which the gas cooled outside the reactor is recirculated to the cooling zone is, and having a predetermined flow of fresh reducing gas that is mainly composed of hydrogen and carbon monoxide, as a first stream, and that one the first stream into a second stream introduced into the reducing gas loop and into one dividing the third stream which is introduced into the cooling gas loop, characterized in that that one keeps the flow rate of the first stream essentially constant and the splitting ratio of the second to the third stream modified so that thereby the in mutual relation standing reduction and carburization reactions caused in the respective reduction and cooling zones and you get a product with a predetermined level of metallization and carburization receives. 2. The method according to claim 1, characterized in that substantially all of the carbon dioxide is removed from the circulating reducing gas before the circulating Reducing gas is returned to the reduction zone. 3. The method according to claim 1, characterized in that substantially the entire amount the fresh reducing gas supplied to the reactor is introduced into the reducing gas loop, to obtain a sponge iron with a metallization of at least 94% and a carbon content less than 1.0%. 4. The method according to claim 1, characterized in that most of the fresh reducing gas is introduced into the cooling loop to produce a sponge iron with a metallization from 80 to 84% and a carbon content of 2.7 to 3.2%.