Patent Application
20150330707
The invention relates to a method for balancing out amount fluctuations while simultaneously increasing the temperature of an export gas used in a reduction process. In this case, a first partial amount of a recycle gas is cooled in at least one recycle gas cooler to form a cold recycle gas. The cold recycle gas is added to the export gas in a pressure-controlled and/or amount-controlled manner, in order to balance out amount fluctuations of the export gas.
The invention further relates to a device for performing the method according to the invention.
Use of an export gas in a reduction process is known from the prior art. The export gas in this case comes from an external gas source such as a plant for producing pig iron and/or a coal gasification plant and/or a coking plant, for example. In this case, the reduction process also includes preparation of the export gas to form a reduction gas, e.g. compression of the export gas in an export gas compressor and elimination of the CO2 from the compressed export gas, before the reduction gas is supplied to a reduction unit for the reduction of metal oxides.
The export gas is often subject to amount fluctuations. This may result in disadvantageous operating states in the reduction process, said states being resolved by means of measures that are known from the prior art, e.g. adding a variable amount of a gas stream to the export gas in order to balance out the amount fluctuations.
In this case, it is disadvantageous that the export gas often has a temperature which is at or just marginally above the dew point of the export gas. If such an export gas is introduced into the export gas compressor, for example, there is a danger that wet/dry transitions may occur as a result of falling below the dew point of the export gas, particularly at inlet guides and impellers of the export gas compressor, and/or that residues may accumulate at the inlet guides and impellers of the export gas compressor due to condensation/sublimation of polyaromatic hydrocarbons in the export gas.
Heat exchangers which may be present and into which such an export gas is introduced may likewise be affected by such accumulated residues.
The object of the present invention is to provide a method and a device by means of which it is possible to overcome the disadvantages that are known from the prior art.
This object is achieved by a method for balancing out amount fluctuations while simultaneously increasing the temperature of an export gas which is used in a reduction process, said method comprising method steps as follows:
An export gas is understood to be a gas which comes from an external gas source. An external gas source is a plant for producing pig iron and/or a coal gasification plant and/or a coking plant, for example. The export gas may also include e.g. crucible gas or blast-furnace gas from the gas network of a steelworks or an integrated iron and steelworks.
The method comprises the cooling of the first partial amount of the recycle gas in the recycle gas cooler. The cooled recycle gas is subsequently referred to as cold recycle gas. The cold recycle gas is added to the export gas in a pressure-controlled and/or amount-controlled manner, in order to balance out the amount fluctuations of the export gas. This pressure-controlled and/or amount controlled supply is effected by means of a recycle gas compressor, for example. According to the invention, the second partial amount of the recycle gas, having a higher temperature than the cold recycle gas, is added to the export gas in a pressure-controlled and/or amount-controlled manner. For clarity, this second partial amount of the recycle gas is subsequently referred to as hot recycle gas. The cold recycle gas and the hot recycle gas each correspond to different partial amounts of the same recycle gas. The cold recycle gas and the hot recycle gas are added to the export gas, the order in which these two gases are added to the export gas being arbitrary. The hot recycle gas may be added to the export gas first, followed by the cold recycle gas, or the cold recycle gas may be added before the hot recycle gas. In the first variant, the export gas already contains the hot recycle gas before the cold recycle gas is added, whereas in the second variant the export gas already contains the cold recycle gas before the hot recycle gas is added.
The invention also comprises the addition of the cold recycle gas and the hot recycle gas to the export gas as a mixture consisting of the cold recycle gas and the hot recycle gas. In this case, the hot recycle gas is mixed with the cold recycle gas first, and the mixture is then added to the export gas. The export gas contains both the cold recycle gas and the hot recycle gas after addition of the mixture.
The addition of the hot recycle gas and the cold recycle gas to the export gas as a mixture has the advantage that only a single line is required for adding the mixture to the export gas, and therefore a very compact structural format is possible.
The export gas contains at least one of the following gas components: carbon monoxide (CO), carbon dioxide (CO2), hydrogen (H2) , nitrogen (N2) , methane (CH4) , water vapor (H2O). The recycle gas contains at least one of the following gas components: carbon monoxide (CO), carbon dioxide (CO2), hydrogen (H2), nitrogen (N2), methane (CH4), water vapor, and can come from any desired gas source.
In this context, a reduction process is understood to signify not only a reduction of metal oxides by means of a reduction gas in a reduction unit, but also all of the method steps that are required to prepare the export gas mixture in order to form the reduction gas.
The export gas containing the cold recycle gas and the hot recycle gas is subsequently referred to as an export gas mixture, which is introduced into the reduction process. The temperature of the hot recycle gas is higher than the temperature of the export gas before the addition of the hot recycle gas and the cold recycle gas to the export gas. Moreover, the temperature of the hot recycle gas is higher than the temperature of the cold recycle gas.
The temperature of the export gas mixture is therefore higher than the temperature of the export gas before the addition of the cold recycle gas and the hot recycle gas.
As a result of adding the hot recycle gas to the export gas, the sensible energy of the hot recycle gas is used to increase the temperature of the export gas. The temperature of the export gas or of the export gas mixture is therefore so adjusted as to be higher than its dew point or its dew point temperature. This operation is known as superheating of the export gas or the export gas mixture. One advantageous effect of this superheating is to avoid wet/dry transitions due to condensation/evaporation of water as a result of falling below the dew point of the export gas mixture, and to prevent an accumulation of residues at inlet guides and/or impellers of the export gas compressor due to condensation/sublimation of polyaromatic hydrocarbons in association with dust particles which may be present in the export gas or in the export gas mixture and/or in the recycle gas. The measures according to the invention also minimize the danger of stress crack corrosion at the impellers of the export gas compressor.
The cold recycle gas preferably has essentially the same temperature as the export gas.
The expression “essentially the same temperature” is understood to mean that the temperatures of the cold recycle gas and the export gas differ by no more than 40° C., preferably by no more than 20° C., and most preferably by no more than 10° C.
In a preferred embodiment variant of the inventive method, a reduction gas obtained from the export gas mixture is introduced into a reduction unit for the reduction of metal oxides, after which the reduction gas is withdrawn from the reduction unit as a top gas after at least partial reduction of the metal oxides, wherein the reduction gas is obtained by method steps as follows:
The elimination of CO2 from the process gas involves e.g. the removal of CO2 from the process gas or the conversion of CO2 into CO, e.g. by means of a reformer as disclosed in the prior art.
The reduction unit is e.g. a blast furnace or a direct reduction unit which is designed on the basis of a fixed bed, fluidized bed or moving bed. Of course, provision may also be made for a plurality of reduction units into which the reduction gas is introduced.
A reduction gas is understood to be a gas which is suitable for reducing metal oxides, particularly iron ores or iron oxides, at least partially to form metals, particularly iron, e.g. a gas which has carbon monoxide and/or hydrogen as its main component.
The metal oxides which are reduced in the reduction unit by means of the reduction gas are referred to as DRI or direct reduced iron. If the reduction unit is designed as a fluidized-bed reactor, the DRI is then briquetted to form e.g. HBI (hot briquetted iron) in order that it can then be reused in an iron or steel production process.
After the metal oxides have been reduced by means of the reduction gas, the reduction gas which is at least partially converted in this way is withdrawn from the reduction unit as top gas. The first partial amount of the top gas, which is preferably dedusted and/or cooled in an apparatus for dust removal and/or cooling, is used as the recycle gas, possibly after compression.
The export gas mixture is compressed in the export gas compressor to form the process gas. The elimination of the CO2 from the process gas is preferably effected by means of pressure-swing adsorption or vacuum pressure-swing adsorption. Elimination of the CO2 from the process gas results in the reduction gas which, before being introduced into the reduction unit, is heated in the reduction gas heating device to a temperature of 700 to 1200° C., which is suitable for performing the reduction of the metal oxides.
The dedusted and/or cooled first partial amount of the top gas is used as the recycle gas, possibly after the compression. The first partial amount of the recycle gas is cooled in the recycle gas cooler to form the cold recycle gas and then added to the export gas. The second partial amount of the recycle gas is added to the export gas as hot recycle gas.
The advantage derived from this embodiment variant of the inventive method is that the thermal energy (so-called sensible heat) contained in the recycle gas is used to increase the temperature of the export gas. Therefore it is not necessary for the hot recycle gas to undergo further heating before it is added to the export gas.
In a further embodiment variant of the inventive method, the lower limit of the temperature of the hot recycle gas is 80° C., preferably 100° C., and the upper limit of the temperature of the hot recycle gas is 180° C., preferably 150° C.
If the temperature of the hot recycle gas lies in the specified temperature range, a corresponding hot recycle gas stream ensures that the temperature of the export gas mixture does not fall below the dew point temperature.
In a further embodiment variant of the inventive method, the export gas includes crucible gas from the gas network of a steelworks and/or comes from a plant for producing pig iron and/or a coal gasification plant and/or a coking plant.
A plant for producing pig iron is e.g. a COREX® plant, a FINEX® plant or an oxygen blast furnace, all of which are known from the prior art. The export gas can therefore also contain or consist of blast-furnace gas from the oxygen blast furnace. If the export gas comes from a coal gasification plant, it may be beneficial to use the pressure energy contained in the export gas in an expansion turbine. The Joule-Thompson effect which occurs when using the pressure energy in the expansion turbine results in a cooling of the export gas. The inventive addition of the hot recycle gas to the export gas balances out the cooling of the export gas and ensures sufficiently high superheating of the export gas.
In a preferred embodiment variant of the inventive method, the export gas undergoes dust removal and/or gas purification in a device for dust removal and/or gas purification before being used in the reduction process, wherein the hot recycle gas and the cold recycle gas are added to the export gas before the dust removal and/or gas purification.
In the device for dust removal and/or gas purification, provision is made for separating out the dust particles or solid particles which are carried along with the export gas mixture.
The removal of dust from the export gas ensures that subsequent components are protected against increased wear or damage caused by dust particles or solid particles carried along with the export gas.
By virtue of adding the hot recycle gas and the cold recycle gas to the export gas before the dust removal and/or gas purification, the export gas containing hot recycle gas is already in a superheated state when it enters the device for dust removal and/or gas purification. This prevents any occurrence of damp operation or wet/dry transitions in this device, and any accumulation of residues in this device due to condensation/sublimation of polyaromatic hydrocarbons which may be present in the export gas.
If the cold recycle gas and the hot recycle gas are added to the export gas as a mixture, the addition of the mixture takes place before the dust removal and/or gas purification of the export gas.
A preferred embodiment variant of the inventive method is characterized in that the temperature of the export gas mixture is at most 50° C., and preferably between 2° C. and 15° C., higher than the temperature of the export gas before the addition of the cold recycle gas and the hot recycle gas.
This ensures that, before compression in the export gas compressor, the export gas mixture is superheated by the addition of the hot recycle gas to the extent that a sufficiently high safety margin exists in relation to the dew point of the export gas mixture.
In a particularly preferred embodiment variant of the inventive method, the temperature of the export gas mixture is regulated to a specific value by the amount of the hot recycle gas which is added to the export gas mixture.
The temperature of the export gas mixture is preferably so regulated as to essentially exceed the dew point temperature of the export gas mixture by a constant value. It is thereby ensured that the dew point of the export gas mixture is exceeded in a constant manner during all operating states of the inventive method.
Further subject matter of the invention relates to a device for performing the inventive method, comprising:
provision is made for a hot recycle gas line which emerges from the recycle gas line and has a second pressure regulating device and/or second amount regulating device that is arranged in the hot recycle gas line, and wherein the cold recycle gas line and the hot recycle gas line flow into the export gas line, or the cold recycle gas line and the hot recycle gas line are combined in a return line which flows into the export gas line.
The export gas or the export gas mixture is introduced into the reduction process by means of the export gas line. In this case, the reduction process comprises e.g. the preparation of the export gas mixture to form the reduction gas, which is then supplied to the reduction unit for reduction of the metal oxides. A recycle gas compressor is preferably arranged in the recycle gas line. After the recycle gas compressor, the cold recycle gas line and the hot recycle gas line emerge from recycle gas line, and both flow into the export gas line or the return line. If the return line is present, it flows into the export gas line. A recycle gas cooler is arranged in the cold recycle gas line. The second pressure regulating device and/or the second amount regulating device is arranged in the hot recycle gas line, preferably taking the form of a position-regulated valve, in particular a hand indicator control or control valve with position indication. Such a valve may also be arranged in the cold recycle gas line.
By virtue of the inventive device features, the export gas can be superheated by means of adding the hot recycle gas. The effect of this superheating is to prevent water droplets from forming as a result of falling below the dew point of the export gas containing the hot recycle gas, i.e. the export gas mixture, and therefore to prevent, in consideration of dust particles which are present in the export gas, any accumulation of residues, e.g. at inlet guides and impellers of the export gas compressor that is present in the reduction process, as a result of wet/dry transitions or condensation/sublimation of the polyaromatic hydrocarbons which may be present in the export gas.
The danger of stress crack corrosion at the impellers of the export gas compressor is also minimized by the measures according to the invention.
A preferred embodiment variant of the inventive device is characterized in that it further comprises:
The reduction gas line, by means of which the reduction gas is introduced into the reduction unit, flows into the reduction unit. The reduction gas, which is at least partially used in the reduction unit during the reduction of the metal oxides, is withdrawn from the reduction unit via the top gas line. An apparatus for dust removal and/or cooling of the top gas is arranged in the top gas line. The recycle gas line branches off from the top gas line after the apparatus for dust removal and/or cooling of the top gas. The recycle gas compressor is preferably arranged in the recycle gas line. The first partial amount of the top gas is supplied to the recycle gas compressor by means of the recycle gas line.
The device further comprises the export gas line in which the at least one export gas compressor is arranged. The export gas mixture is compressed in the export gas compressor to form the process gas. The CO2 eliminating device, for eliminating the CO2 from the process gas while obtaining the reduction gas, is arranged in the export gas line and downstream of the export gas compressor. The CO2 eliminating device is preferably a PSA or VPSA system. The reduction gas heating device for heating the reduction gas is arranged downstream of the CO2 eliminating device. A process gas cooler is optionally situated in the export gas line between the export gas compressor and the reduction gas heating device.
The advantage derived from this embodiment variant of the inventive device is that the thermal energy (so-called sensible heat) contained in the recycle gas can be used to increase the temperature of the export gas. Therefore it is not necessary for the hot recycle gas to undergo further heating before it is added to the export gas.
In a further embodiment variant of the inventive device, the export gas line emerges from a gas network of a steelworks and/or from a plant for producing pig iron and/or from a coal gasification plant and/or from a coking plant.
A plant for producing pig iron is e.g. a COREX® plant, a FINEX® plant or an oxygen blast furnace, all of which are known from the prior art.
An embodiment variant of the inventive device is designed such that a device for dust removal and/or gas purification is arranged in the export gas line, wherein the hot recycle gas line and the cold recycle gas line or the return line flow into the export gas line before the device for dust removal and/or gas purification.
The device for dust removal and/or gas purification is preferably a dry dust removal device which is based on filter bags or filter cartridges.
The hot recycle gas line and the cold recycle gas line flow into the export gas line before the device for dust removal and/or gas purification. In a preferred variant of the inventive device, the return line flows into the export gas line before the device for dust removal and/or gas purification. In this context, the expressions before and after are to be interpreted in relation to the gas flow direction of the export gas.
The dedusting of the export gas by means of the device for dust removal and/or gas purification ensures that subsequent components such as e.g. the export gas compressor, the process gas cooler, the CO2 eliminating device and the reduction gas heating device, are protected against damage by solid components such as e.g. dust particles which are carried along with the export gas.
By virtue of adding the hot recycle gas to the export gas before the latter is dedusted in the device for dust removal and/or gas purification, the export gas containing the hot recycle gas is already in a superheated state when it enters the device for dust removal and/or gas purification. This prevents any occurrence of wet/dry transitions in the device for dust removal and/or gas purification, and any accumulation of residues in the device for dust removal and/or gas purification due to condensation/sublimation of polyaromatic hydrocarbons which may be present in the export gas.
The invention is explained in greater detail below with reference to exemplary and schematic figures, in which:
The export gas 2 undergoes dust removal and/or gas purification in a device 17 for dust removal and/or gas purification before it is used in the reduction process 1. The arrows in
As a result, the temperature of the export gas mixture 8 is higher than the temperature of the export gas 2 before the addition of the cold recycle gas 6 and the hot recycle gas 7. As a result of adding the hot recycle gas 7 to the export gas 2, the sensible energy of the hot recycle gas 7 is used to increase the temperature of the export gas 2. The temperature of the export gas 2 or of the export gas mixture 8 is therefore so adjusted as to be higher than its dew point or its dew point temperature. This operation is known as superheating of the export gas 2 or the export gas mixture 8. One advantageous effect of this superheating is to avoid wet/dry transitions due to condensation/evaporation of water as a result of falling below the dew point of the export gas mixture 8, and to prevent an accumulation of residues at inlet guides and/or impellers of the export gas compressor 12 due to condensation/sublimation of polyaromatic hydrocarbons in connection with dust particles which may be present in the export gas 2 or in the export gas mixture 8 and/or in the recycle gas 4. The measures according to the invention also minimize the danger of stress crack corrosion at the impellers of the export gas compressor 12.
Although the invention is illustrated and described in detail with reference to the preferred exemplary embodiments, the invention is not restricted to the example disclosed herein, and other variations may be derived therefrom by a person skilled in the art without thereby departing from the scope of the invention.
1 Reduction process
2 Export gas
3 First partial amount of the recycle gas
4 Recycle gas
5 Recycle gas cooler
6 Cold recycle gas
7 Hot recycle gas
8 Export gas mixture
9 Reduction gas
10 Reduction unit
11 Top gas
12 Export gas compressor
13 Process gas
14 CO2 eliminating device
15 Reduction gas heating device
16 First partial amount of the top gas
17 Device for dust removal and/or gas purification
18 Export gas line
19 Recycle gas line
20 First pressure regulating device and/or first amount regulating device
21 Cold recycle gas line
22 Hot recycle gas line
23 Second pressure regulating device and/or second amount regulating device
24 Return line
25 Reduction gas line
26 Top gas line
27 Apparatus for dust removal and/or cooling of top gas
28 Mixture
29 Process gas cooler
| Number | Date | Country | Kind |
|---|---|---|---|
| 12198903.2 | Dec 2012 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2013/071250 | 10/10/2013 | WO | 00 |
