versión On-line ISSN 2411-9717
versión impresa ISSN 0038-223X
J. S. Afr. Inst. Min. Metall. vol.111 no.10 Johannesburg oct. 2011
Some considerations on future developments in ferroalloy furnaces
University of the Witwatersrand, Johannesburg, South Africa
This paper argues that the scale up of furnaces and the supply of electricity are going to be two major issues that will affect the ferroalloy industry in the near future, and that economic factors will drive this development.
The most common type of furnace for producing ferroalloys at present is the submerged-arc furnace with three electrodes, fed from a three-phase AC electrical supply. The scale up of this technology has now reached a fundamental constraint, which is caused by the electrical reactance of the secondary circuit. If the economy of any further scale up is to be achieved in the future then a different technology will have to be used.
The supply of electrical power in future is likely to become a more complex issue than it is at present. Existing submerged-arc furnaces tend to run at fairly steady loads, but the ability to swing the load under demand-side management may offer advantages, and may allow a furnace to obtain cheaper power from the organizations that supply this power. This will have to be counterbalanced against the nuisance factors incurred by having a varying load in the operation of the furnace.
Various options are therefore discussed in this paper. The possibility of scale up of Søderberg electrodes is discussed, as well as the use of DC power and multiple electrodes. Some of the issues with load swinging are also examined. A particular scenario is also briefly presented to show that considerable further scale up of ferroalloy furnaces is still possible.
Keywords: submerged-arc furnace, plasma furnace, DC furnace, scale up, Søderberg electrodes, smart grid, demand-side management, load shedding
The basic technology used for producing the bulk of ferroalloys worldwide has not changed dramatically for several decades. There have been some notable developments such as DC plasma furnaces, pollution reduction technology, prereduction technology, control and information systems, and various progressive refinements of the technology, but the standard workhorse still remains the submerged-arc furnace with three electrodes arranged in a circle and fed from a three-phase AC supply.
Up to the late 1960s, submerged-arc furnaces tended to be somewhat smaller than they are today. Then around the early 1970s, new installations with significantly larger capacities started to appear. The main motivation for this would seem to have been the economy of scale. As the sizes increased, other problems started to appear that had not been evident with the earlier smaller furnaces, and this effectively constrained further scale up. However, the production from one of the larger of the present ferro-alloy furnaces is of the order of only 10 000 metric tons per month, while in comparison the output of a larger-sized blast furnace is of the order of 300 000 tons per month. Although these numbers are very approximate, they do reveal a dramatic difference. This would seem to suggest that the motivation for further scale up of ferro-alloy furnaces would still be present if the various constraints could be overcome.
A further consideration is that the future environment in which ferroalloy furnaces will need to operate is likely to be different from the present. One factor that stands out is that the supply of electrical energy is likely to become more restrictive, but also more machine-intelligent. Within such constraints, the ability to swing load is likely to have economic advantages, but present-day submerged-arc furnaces are not easily able to do this.
The above issues all suggest that further developments are now needed. The purpose of this paper is therefore to table a number of the factors involved, and to make suggestions as to how some of these factors might be addressed.
It has been argued that sustainability issues also need to be addressed by the industry in future (see, for example, Dos Santos1). The ability to swing load as described here will be a fundamental requirement for the industry to use more 'green' energy than it is able to accept at present. Other 'black swan' factors2 may also influence future developments, but, by their very nature, they are difficult to predict in advance. Not only are the two issues discussed in this paper clearly evident now, but also there are practical ways of evolving the technology to deal with both of them.
Current constraints on the scale up of submergedarc furnaces
It is perhaps not surprising that problems associated with scale up tend to be found more often on larger furnaces. Generally, these problems are associated with the operational side of the furnaces. Many basic factors are involved in such problems, but with regard to scale up, two stand out in particular:
Scale up of the electrical circuit-As this type of furnace is scaled up, the reactances increase while the resistances decrease. When the reactances become comparable to or larger than the resistances, the behaviour of the electrical circuit becomes problematic3. This leads to difficulties with the measurement of the electrical state of the furnace, and consequently with the control of the electrodes
Scale up of the electrodes-A given Søderberg electrode is limited in the current that it can carry. Scaling up to higher currents requires larger electrode diameters, but these larger electrodes would seem to be more prone to problems. These problems can probably be ascribed to two main mechanisms. Firstly, the mechanical strength of any structure gets weaker as the structure is scaled up in size. This is because the weight rises by the cube of the linear dimension while the strength rises by only the square of the dimension. Secondly, there is the issue of the skin effect associated with the AC current in a Søderberg electrode. This is an electromagnetic phenomenon in which the current density is higher nearer to the surface than within the bulk of a conductor. In the carbon part of a Søderberg electrode, the skin depth is of the order of 0.3 to 0.4 m. Hence, in a small electrode the skin effect is not significant, but for diameters larger than about 1.2 to 1.5 m the centre tends not to receive enough current to heat it at the same rate as the rest of the electrode.
To people directly involved with a larger furnace that is giving trouble, the above underlying factors usually do not reveal themselves as such but as a syndrome of endemic problems such as recurring broken electrodes including apparent tip breaks, unbalanced electrodes, low power factor, tapping difficulties, hot roofs, off-grade product, higher MWh/t, and so on.
The frequency of the AC electricity mains plays a part in both the above factors-the reactances are proportional to frequency, while the skin depth is inversely proportional to the square root of frequency. Hence, a lower frequency would benefit both. This also suggests that DC current might help to alleviate some of the problems. However, while DC current might obviate the skin effect, it plays no direct part in the mechanical strength of the Søderberg electrode. At this stage, we do not know whether it is the strength or the skin effect that is the main constraint on the scale up of the electrodes. This will become apparent only once large Søderberg electrodes have been tried in a DC application in practice.
The supply of electrical energy
Ferroalloy furnaces use large amounts of electrical energy, and the future availability of such energy is becoming a concern. Firstly, throughout the world, electricity generation based on the combustion of carbonaceous fuels is becoming less favoured while widespread use of nuclear energy remains controversial, but there is a push towards renewable sources of energy for the future generation of electricity. Solar power and wind power are typical examples of such renewable resources. Secondly, in South Africa at present, the generating capacity is somewhat limited. The ferroalloy industry has felt the effects of this in various ways. In particular there is an ongoing concern that there might be insufficient generating capacity to meet peak demand, particularly at times when the demand is high or when several generators have to be taken out of service simultaneously.
The purpose of this paper is not to review the energy problems facing the world, but it is necessary to briefly discuss the ways in which some of the options can be handled. For this purpose, Figure 1 shows a very simplified schematic of an electricity distribution system. This figure is intended to show how electrical power is generated by a number of suppliers and then fed into a common grid to be distributed to a number of users. At all times the production of electrical power must match the consumption-there can be no excess or shortfall. This is unlike, for example, a water reticulation system where there are intermediate reservoirs that serve as buffers between the supply and the demand. Of course, there are ways to store electrical energy when it is available in excess and to return it to the grid when it is needed. Pumped water storage schemes are a relatively common example of this. Such an arrangement is not shown explicitly in Figure 1, although it can be modelled as a combination of a user and a supplier. The main purpose of Figure 1 is simply to emphasize the balancing of power between suppliers and users at any given time.
This balancing of the power requires that the output of the generators be adjusted continuously to match demand. The actual control of this over a number of suppliers is a fairly complicated issue. It also depends on the time scale involved, as the sub-second control has to be done with the equipment that is already running, whereas for hour-to-hour up to day-to-day control it is also possible to bring in or take out modules in the supply side or demand side.
The sub-second control is based in essence on the frequency of the AC as well as on the voltage. If, for example, a user starts to draw more power, then the rotating generators of the suppliers will start to slow down as much of this energy will come initially from the kinetic energy in their rotation. This decrease in frequency will be detected and the control system will then automatically increase the steam fed to the turbines to make these generators speed up again.
Often, some of the suppliers cannot easily change their output. In this case, other suppliers have to handle all the changes when there is a variation in demand. The biggest problem that can occur is when there is insufficient reserve capacity on the generating side to increase the output any further when it is needed. This can happen when all the suppliers are generating at their respective maximum outputs.
Unfortunately, there is a problem with most large-scale renewable sources of energy in terms of their controllability. Consider a wind turbine, for example. Not only can it produce electricity only when the wind strength is sufficient, but also it cannot increase its output if it is already generating at maximum. Such a turbine would therefore have to be run below its maximum output if it is to have the reserve capacity to handle fluctuating loads. Alternatively, there would have to be some other generator that handles the fluctuations.
Another way to handle variations in demand is to shed some of the loads drawn by the users. This is the concept of demand-side management.
The smart grid
This has been a subject of much debate recently. In essence, the technology is now becoming available to pass information at fairly high speed between the various stakeholders on the grid, and this opens up a number of possibilities. For example, 'intelligent' demand-side management on ferroalloy furnaces becomes a distinct possibility, whereas up to now it has been virtually out of the question.
The use of ferroalloy furnaces for demand-side management
Ferroalloy furnaces generally have been regarded as reasonably steady base loads on the power grid, unlike many of the other loads on the grid that fluctuate with the time of day, the weather, and various other factors. It used to be argued that a steady base load like this is beneficial to the power producers as it lessens the ratio of the fluctuations to the total load.
However, if a large base load like a ferroalloy furnace can be swung as needed, then it can also be used to absorb some of the fluctuations caused by other loads. Organizations that supply and distribute power should react favourably to such users, and it is not unreasonable to expect cheaper tariffs in return. The problem is that present-day submerged-arc furnaces are rather limited in their ability to vary their load in this way.
It is tempting to dismiss the concept of varying the load on a ferroalloy furnace as an unnecessary nuisance, but eventually economics will decide-the plant that can tolerate fluctuations on demand will get cheaper power than the plant that has to run at a steady load. Also, power users that can offer a variable load on demand to their electricity supplier may be treated more favourably in return.
Some possible ways for the ferroalloy industry to adapt to changes
Figure 2 shows the schematic layout of the existing common type of submerged-arc furnace, with three transformers feeding the three electrodes in the common knapsack arrangement.
The first obstacle to scaling up is the supply of 3-phase power from the AC mains direct to the furnace electrodes, in the manner shown in Figure 2. This is because the inductances in the furnace circuit at the frequency of the AC mains are simply too large. This obstacle is a fundamental problem with the basic circuit, so some alternatives will have to be found if the industry is to get around this constraint.
A related problem with this arrangement is that all three electrodes are part of the same circuit, so that when there is a problem on one electrode, the other two electrodes are likely to be affected as well. This interaction effect3between electrodes gets worse with decreasing power factor, and hence is also a constraint that inhibits scale-up.
One fairly obvious possibility is the use of DC on existing submerged-arc furnaces in place of AC power. Figure 3 shows a suggested arrangement for doing this, with each electrode fed from its own DC supply. Note that the three boxes shown in Figure 3 are now DC power supplies, not simply AC transformers as shown in Figure 2. The advantage of this configuration is that each electrode can then be handled on its own, as each electrode and its power supply is a separate circuit.
One way to test this arrangement might be to retrofit an existing AC furnace, i.e. to use the infrastructure of an existing AC furnace, but in particular replace the hearth by one with anode connections, and replace the transformers with DC power supplies.
The DC power supplies on furnaces like this should be fairly amenable to fast demand-side management should the need arise in future. This could be an attractive feature to organizations that are involved in the supply of power.
DC plasma furnaces (also known as DC arc furnaces) offer another approach, and also they are now proven commercially. Being inherently DC, they avoid any problems with AC reactance. However, the metallurgy is somewhat different, so a direct comparison with a submerged-arc furnace is difficult. A 60 MW furnace of this type has recently been commissioned at Middelburg4,5.
In comparison with submerged-arc furnaces of similar power, DC arc furnaces tend to run at higher voltages and lower currents. Because of these lower currents, they have smaller electrodes. They also normally use graphite electrodes, but the diameters of these graphite electrodes on the larger furnaces are already close to their upper limit. However, further scale-up would still be possible using multiple electrodes, and arrangements like that shown in Figure 3 might also work for DC arc furnaces.
The DC power supplies on plasma furnaces should also be fairly amenable to fast demand-side management.
Constraints on electrodes
Søderberg electrodes are reputedly cheaper than pre-baked or graphite-type electrodes, but they tend to be more complicated to use. They are the normal type of electrode used in existing AC submerged-arc furnaces, but potentially they could also be used with DC in submerged-arc furnaces, and possibly also in DC plasma furnaces. These other applications need further development as they are still largely untried.
This use of DC current will overcome the skin effect, and so might allow Søderberg electrodes in submerged-arc furnaces to be scaled up beyond the present limit of about 2 m diameter. Larger electrodes will allow higher current and higher power per electrode, and so are one avenue towards further scale up of furnaces.
During a furnace shutdown, after the current through a Søderberg electrode is turned off, the electrode cools down slowly with time. Later, when the current is restored, the electrode proceeds to heat up again. The contraction and expansion that results from this thermal cycling during furnace shutdowns tends to stress an electrode mechanically and can lead to breakages. Computer modelling6has made it possible to study the time evolution of this heating and cooling and the resulting mechanical stresses. This has shown, for example, that with electrodes of about 1.5 m in diameter, the time constant of this cooling and heating in the bulk of the electrode is of the order of about 4 hours, although some small regions inside the electrode near to the lower ends of the contact shoes do tend to heat and cool faster than this. It is perhaps not surprising that common wisdom in the industry advises that furnace shutdowns longer than about 4 hours have to be followed by baking in of the electrodes, while for shorter shutdowns one can often get away without baking in.
In some parts of the world, ferroalloy plants shut their furnaces off for a short period during the peak demand time each evening. This period is usually about 2 hours, which is safely less than the 4 hours discussed above for cooling and heating of the electrodes.
Fundamental energy-transfer theory tells us that the time constant for cooling and heating of a long cylinder should be proportional to the square of the diameter. Hence, if the time constant for an electrode with a diameter of 1.5 m is about 4 hours, then for an equivalent electrode of, for example, 3.0 m diameter it should be about 4 times longer, i.e. 16 hours. (This would apply only to electrodes carrying DC current, not AC). This suggests that larger electrodes, if they are viable, may be able to tolerate significantly longer shutdowns. Hence for load shedding in demand-side management, it may be possible for plants to offer their electricity suppliers longer shutdowns if they have larger electrodes together with DC currents.
Swinging the load
Most furnaces at present run close to full power for most of the time, but if a ferroalloy furnace is going to be used for demand-side management, then obviously the load is going to have to be varied.
Possibly the biggest problem in implementing such a concept will be to get acceptance from the plant management team to allow some external factor to vary the furnace load seemingly at random!
Consider the issue of selecting an electrical operating point when a submerged-arc furnace has to be run at low load for an extended period. One option is to adhere to a constant resistance so that power scales down by simply the square of the electrode current. Another option is to keep to a constant Westly C3 factor7, which effectively increases the resistance at lower load. A third option is to decrease the resistance at lower load so that the electrode currents stay relatively higher in order to keep the electrodes baked. Yet another option is to switch the furnace off altogether, but this can be done only for a relatively short period. It is perhaps surprising that this difficulty in choosing an operating point for a reduced load is not a new problem-Westly himself was already well familiar with this issue over 37 years ago8-and yet it still remains an area of uncertainty.
Swinging the load on a submerged-arc furnace is actually a more complex issue than just choosing an operating point as discussed above. When a furnace's load decreases, the metallurgy of the process will be affected. But this is not all; in a conventional AC furnace, changing the resistance set-point will alter the power factor and so affect the electrical measurability and controllability of the furnace as well. Indeed it will probably be easier to swing load on DC furnaces than on AC furnaces because DC decouples the electrodes and so avoids this measurability and controllability issue. Also, the baking of the electrodes is going to be affected as well as the slipping and erosion of the electrodes. This will make tracking of the electrode length difficult, which will aggravate the electrical measurability and controllability problems. Going from one load level to another may be done as a step, but the responses will have transients with a wide range of time constants. Furthermore, other parts of the plant like the gas cleaning section may work differently at lower loads, and the management of the tapping floor and the raw materials would have to be much more flexible.
From this it is clear that any implementation of load swinging is going to have to be done gradually and in an evolutionary manner, as much still remains to be learnt about the consequences. It will not be something that can be implemented in a large step-like change. Also, the entire plant should be designed to allow the process to run at differing loads.
This evolution of load swinging would benefit if improved online information systems could be made available to assist with the more complex operational requirements. This would include facilities such as online computer-based simulation models that enable the operations team to 'see' such things as the baking of Søderberg electrodes and the tracking of electrode length. This would require more rugged and reliable instruments for measuring plant variables like the slipping of the electrodes. The information system would also tie in to the smart grid network, and include various predict-ahead planning facilities. Such information systems will need time for development and refinement.
A larger furnace
The furnace design outlined in this section is intended as a hypothetical exercise into what might be the next ceiling on the scale up of ferroalloy furnaces. It is one of several possible scenarios, most of which are still relatively unproven.
The proposed design is a 6-electrode furnace with the electrodes arranged in a circle, as outlined in Figure 4. Each electrode would be fed by its own power supply module as shown, using DC power in much the same way as the arrangement in Figure 3. Let us consider a submerged-arc furnace here, although the same layout and supply could probably also be used with a plasma furnace.
Let us also consider using Søderberg electrodes, taking a nominal diameter of 3.0 m for these electrodes, as this only about 50% larger than the largest electrodes that are currently in use on submerged-arc furnaces. Time might prove that even larger electrodes than this will work, but it might also show that even just this diameter is simply not attainable.
Table I summarizes a comparison between a typical submerged-arc furnace at present and a furnace of the design proposed here. It reveals a significant increase in power level with this proposed design, which suggests that the scale up of ferroalloy furnaces to well beyond the present production levels should be a goal that the industry can reach.
The economy of scale creates an inexorable push towards larger furnaces in the ferroalloy industry. However, the AC type of submerged-arc furnace as is commonly used at present has certain fundamental limits, and so conversions to other forms of furnace are likely. Once this 'AC barrier' has been overcome, scale up will probably involve larger electrodes and more electrodes. This could be applied to either plasma furnaces or submerged-arc furnaces. The potential for the scaling up of Søderberg electrodes will be known only once this AC barrier has been overcome and larger furnaces have been tried in practice.
The supply of electrical power to ferroalloy furnaces is likely to become a more complex issue in the future because of constraints and other factors external to the industry, and because of the evolution of information technology. The ability to swing the furnace load is likely to bring significant economic advantages, and so might become common practice in spite of the nuisance factors that this will incur with the operation of the plant. This will also require more computer-based support for the supervision and control of the plant, as well as a tie-in to the so-called 'smart grid'. It would seem that larger furnaces might also be better than current furnaces at handling power dips and outages for a longer time, and DC arrangements could offer significant advantages when it comes to easy and fast swinging of the load.
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This paper was first presented at the Southern African Pyrometallurgy Conference, 6-9 March 2011, Misty Hills, Muldersdrift.
© The Southern African Institute of Mining and Metallurgy, 2011. SA ISSN 0038-223X/3.00 + 0.00.