SE534084C2 - Process for increasing the heat homogeneity in a pit oven - Google Patents

Abstract

Process for increasing the heat homogeneity in a pit furnace (200; 300) in which at least two wells (20l; 30l) as. should be heated to be inclined towards each of the respective first and other opposite inner cradles of the pit furnace (200; 300) so that the groove (20l; 30l) forms an elongate space (203; 303) with V-shaped cross-section between them seen along the first and second cradles. The invention is characterized by the fact that at least one lance (211, 212, 221, 222; 311, 312, 321, 322) is separated by an oxidant Ined. an oxygen content of at least 85% by weight oxygen and at least one separate lance (20, 220; 310, 320) for fuel are arranged to be arranged in an oven cradle so that they open inside the furnace (200; 300) at a distance from each other and so that oxidant-respective fuel caused to be supplied to said V- (203; 303) (211, 212,22l, 222; 311, 312,32l, 322) shaped space and there are burned, and by the lance for oxidant being arranged to open above the fuel lance ( 20, 220; 310, 320) orifice and to be directed so that the oxidant flows obliquely downwards and along the said longitudinal direction of the said V-shaped outlet (203; 303). Application text document, 2010-05-04 100080SE,

Description

It is especially common that the upper parts of the ingot risk overheating at the same time as the lower parts become too cool.

There are limited possibilities to control the combustion reaction to cooler parts of the furnace, due to the risk of local overheating in the vicinity of the combustion site. It is also generally not possible to compensate for the reduced amounts of combustion gases by increasing the power of oxyfuel burners. Arranging a large number of oxyfuel burners in one and the same oven is possible, but very expensive. In addition, the result is still not good, as it is desirable to be able to heat different numbers of ingots in the same oven at different times.

The present invention solves the problems described above.

Thus, the invention relates to a method for increasing the heat homogeneity in a pit furnace in which at least two ingots to be heated are caused to be inclined against each of the respective first and second opposite inner walls of the pit furnace so that the ingot forms an elongate space with a V-shape. cross-section between them seen along the first and second wall, and is characterized in that at least one separate lance for an oxidant with an oxygen content of at least 85% by weight of oxygen and at least one separate lance for fuel are arranged in a furnace wall so that they and inside the furnace at a distance from each other and so that oxidant and fuel are caused to be supplied to said V-shaped space and burned there, and by causing the lance for oxidant to be arranged to open above the mouth of the fuel lance and to be directed so that the oxidant flows obliquely downwards and along the longitudinal direction of said V-shaped space. The invention will now be described in detail, with reference to exemplary embodiments of the invention and the accompanying drawings, in which: Figure 1 is a partially sectioned perspective view showing a conventional pit furnace; Figure 2 shows the pit furnace according to figure 1 from the long side; Figure 3 shows the pit furnace according to Figure 1 from above; Figure 4 is a partially sectioned perspective view showing a pit furnace according to a first preferred embodiment of the present invention; Figure 5 shows the pit furnace according to Figure 4 from the long side; Figure 6 shows the pit furnace according to Figure 4 from the short side; Figure 7 shows the pit furnace according to Figure 4 from above; Figure 8 is a view similar to that of Figure 5 but showing a pit furnace according to a second preferred embodiment according to the present invention from the long side; Figure 9 shows the pit furnace according to Figure 8 from the short side; and Figure 10 shows the pit furnace according to Figure 8 from above.

Figures 1-3 illustrate, with common reference numerals, a conventional pit furnace 100 in which ten ingots 101 are heated in two rows of five ingots each. The ingot rests on a bed 102 of embers from previous runs, and is inclined in two rows against the opposite inner walls of the furnace 100 along the longitudinal direction 104 of the furnace 100.

The furnace 100 is heated by means of a conventional air burner 103, directed in the longitudinal direction 104 of the furnace 100. The air burner 103 is arranged in the wall at one short end of the furnace 100. Since the furnace 100 is shown partially broken away in Figures 1-3, said short end is not shown 100 roofs and its 10 15 20 25 30 534 084 one long side. The hot combustion gases from the air burner 103 flow in the direction 104 along the rows of ingots 101, and turn at a distal short end 105 of the furnace to flow back to the short end in which the air burner 103 is arranged, and there are removed through an exhaust duct 106 for flue gases. . Since the air burner 103 and the outlet duct 106 are arranged in the same wall in the furnace 100 but at different heights, a natural convection occurs which results in sufficient temperature homogeneity in the entire furnace space.

Figures 4-7 show, with common reference numerals, a pit furnace 200 in which a method for increasing the heat homogeneity according to the present invention is applied. The furnace 200 is partly similar to the furnace 100 shown in Figures 1-3. In the furnace 200 a number, at least two, ingots 201 are arranged. The ingot 201 is arranged in two rows along the main longitudinal direction 250 of the furnace 200, inclined towards each of the respective first and second opposite inner walls of the pit furnace 200 so that the ingot 201 forms a space 203 with a V-shaped cross section (see Figure 6) between and above it along said first and second inner walls. Said inner walls preferably consist of the longitudinal inner walls of the oven 200. Figures 4-7, which are partially broken away, do not show one of said walls.

The ingot 201 rests against a bed 202 of embers which is similar to the bed 102. Alternatively, the ingot 201 can rest directly against the oven floor.

An exhaust duct 206 for flue gases is arranged in one short side of the furnace 200.

It is preferred that at least one separate lance 211, 212, for oxidant and at least one separate lance 210 for fuel are arranged in an oven wall so that they open inside the oven 200 at a distance from each other and so that oxidant respective fuel can be supplied to the V-shaped space 203 between the ingot 201 and there react.

The lower fuel lance 210 and the two oxidant lances 211, 212 opening above the mouth of the fuel lance 210 together form an assembly or group of lances. The unit can also be designed with other configurations of lances for fuel and oxidant, as long as at least one oxidant lance opens above at least one fuel lance.

It is preferred that the distance between each oxidant and fuel lance be at least 5 cm.

According to the invention, the oxidant supplied via at least one, but preferably via all, lances for oxidant has an oxygen content of at least 85% by weight of oxygen, preferably at least 95% by weight. The fuel can be any suitable, conventional, gaseous, liquid solid fuel, such as oil or natural gas. It is preferred that the fuel be a gaseous or liquid fuel.

It is preferred that at least one of the oxidant lances 211, 212, preferably all of the lances 211, is an oxidant, arranged to open above the mouth of at least one fuel lance 210, and directed so that the oxidant flows obliquely downwards and along the longitudinal direction of the V-shaped space 203, substantially parallel to said first and second furnace walls. In other words, the oxidant is supplied to the V-shaped space 203 between the ingots 201, so that the obliquely downwardly directed stream of oxidant runs in the longitudinal direction 250 of the furnace 200. It is further preferred that the stream of oxidant from each of the oxidant lances 211, 212 is arranged to cut through an area in the space 203 to which fuel is supplied by means of the fuel lance 210. Preferably, at least one stream of oxidant and at least one stream of fuel meet in the space 203.

Since the oxidant has such a high content of oxygen, the amount of hot combustion gases originating from the fuel and the oxidant supplied through the lances 210, 211, 212 will be substantially less than the corresponding amount of combustion gases originating from the air burner 103 for corresponding heating effects. As described above, operation with such an oxidant conventionally gives rise to impaired temperature homogeneity. In particular, it has proved difficult to achieve a sufficiently high temperature towards the bottom of the V-shaped space 203 between the ingot 201, i.e. in the vicinity of the shell bed 202 at the bottom of the furnace 200, and in the space 205 (see Figure 6) with triangular cross-section located below the ingot 201, between each ingot 201 or row of ingots and the oven wall against which the ingot or ingot 201 is inclined.

The oxidant thus flows out of the lances 211, 212, meets the fuel flowing out of the fuel lance 210 in the V- and shaped space 203 between the ingot 201. By supplying the oxidant in this way through a separate lance, the geometric shape and speed of the oxidant flow is regulated so that it can carry the resulting mixture of fuel and oxidant down to the bottom of the V-shaped space 203. Thus, the temperature there can be increased without increased risks of overheating, which would have been the case if, for example, an air burner had been placed closer to the bottom or if a separate oxidant lance had been placed so that it immediately opened in the immediate vicinity of the ingot 201. 10 15 20 25 30 534 084 The fuel lance 210 may be arranged horizontally and so that the fuel flow is directed substantially straight along the main longitudinal direction of the V-shaped space 203. However, it is preferred that the fuel lance be slightly angled downward relative to the horizontal plane with an angle of at most 5 °. The respective oxidant currents from the lances 211, 212 are in this case directed at the same or greater angle in relation to the horizontal plane.

Thus, the downward oxidant stream can carry the combustion mixture downward toward the bottom of the V-shaped space 203.

According to a preferred embodiment, at least one oxidant lance 211, 212 opens above all fuel supply points, in the present example the fuel lance 210, which is arranged in the same furnace wall in which the oxidant lance 211, 212 in question opens. This means that all fuel supplied via the assembly of lances 210, 211, 212 in question is carried downwards in the V-shaped space 203 by means of the oxidant stream from the lance in question.

According to a particularly preferred embodiment, the oxidant 212 is supplied to the oxidant lance 212 which opens at the top of each respective ten through at least one oxidant lance 211, preferably aggregate, at high speed. This results in increased convection in the furnace space, which compensates for the smaller amounts of combustion gases in comparison with if one or more air burners had been used 211, instead of the oxyfuel burner which the lance unit 210, 212 constitutes.

It is preferred that the launch speed is at least 100 m / s, which in many applications entails sufficient convection in the furnace space. Furnace atmosphere gases are sucked into the combustion mixture, which lowers the combustion temperature and thus results in lower formed NOX. In combination with the downward oxidant flow described above, the entire furnace space, including the bottom of the V-shaped space 203, will then become sufficiently hot without risk of local overheating.

According to a particularly preferred embodiment, oxidant is launched through at least one oxidant lance 211, 212 at a speed which is at least the speed of sound. This leads to a sharp increase in convection and recirculation in the entire furnace space, with correspondingly greatly improved temperature homogeneity and reduced values for CO and NOX. Such a method is especially preferred in larger ovens.

Most preferred is to supply oxidant through at least one oxidant lance 211, 212 at at least mach 1.5. Such a high launch speed has been found to cause a convection that increases as a function of the speed in a non-linear manner. Above about mach 1.5, a combustion of the flameless type can be achieved where the combustion can take place in most of the furnace space at the same time, without a clearly distinguishable flame. This therefore results in very good temperature homogeneity even in hard-to-reach parts of the oven space.

It is preferred that at least one oxidant lance 211, 212, preferably each oxidant lance, is mounted so that the respective oxidant flows out into the oven space at an angle of more than 0 ° and at most 20 °, preferably between 13 and 5 °, relative to the horizontal plane. Thus, at least one oxidant lance 212 is angled from a horizontal position in the direction indicated by the arrow 251.

This results in a pit furnace 200 of normal size that the mixture of oxidant and fuel is lowered far enough towards the bottom of the V-shaped space 203 for the desired temperature homogeneity to be achieved. According to a particularly preferred embodiment, more than 212 are used, as illustrated in Figures 4-7. an oxidant lance 211, arranged to open above each other. In this case, it is preferred that the downward angle, relative to the horizontal plane, with which the resulting oxidant flow is directed, is equal to or greater for oxidant lances 212 which open further up than for oxidant lances 211 which open further down. In the present exemplary case of two oxidant lances 211, 212, it is then preferred that a lower oxidant lance 211 has an angle of more than 0 ° and at most 10 ° while an upper oxidant lance 212 has an angle of more than 0 °. and at most 20 °, but at least the same angle as the upper oxidant lance 212. By arranging several oxidant lances one above the other in this way, the total flow of fuel and oxidant can be controlled so that a good spread of fuel and oxidant can be achieved. in space 205.

In the exemplary embodiment illustrated in Figures 4-7, a first group of lances or lance assemblies, comprising a fuel lance 210 and two oxidant lances 211, 212, arranged in one short side of the furnace 200, and a second lance assembly, lugs 221, comprising one fuel lance 220 and two oxidant lances 222, are arranged in the second, opposite short side of the furnace 200. Both lance assemblies thus comprise a respective fuel lance 210, 220 above whose mouth two and 212, 221, holes, respectively, may be formed with other configurations of lances for oxidant lances 211, 222 mouths. Each such aggregate fuel and oxidant, as long as at least one downward oxidant lance for oxidant with more than 85% by weight of oxygen opens above at least one fuel lance in each aggregate. As is clear in Figures 5 and 6, the two lance assemblies are arranged at different heights in the furnace 200. By such an arrangement, the temperature homogeneity can be further increased by circulating effects occurring in the furnace space. In this case, it is preferred that the lowest opening fuel lance 210 in a first assembly of lances 210, 211, 212 is arranged to open at a height above the furnace floor which is between 0.7 and 1.2 meters above the level above the furnace floor at which the lowest mouth lance 220 in a second assembly of lances 220, 221, 222 mouths. It is further preferred that all such assemblies of fuel and oxidant lances 210, 211, 212, 220, 221, 222 which open into the V-shaped space 203 are arranged so that no lance opens into the furnace at a vertical level from the furnace floor. which is so large that overheating of the ingot 201 is risked as a direct consequence of the heat energy supplied locally as a result of the fuel or oxidant supplied through such a lance. What this vertical level is depends on the design of the furnace 200 and the location and shape of the ingot 201, but it is preferred that no such lance opens at a level less than 1.5 meters above the floor.

Figures 8-10, the views of which correspond to the views of Figures 5-7, illustrate an alternative embodiment, in which, in a manner similar to that described above in connection with Figures 4-7, a pit furnace 300 contains ingot 301 resting against a scale bed 302 and is heated by means of two opposing units of lances 310, 320 for fuel in combination with lances 311, 312, 321, 322 for oxidant. Arrow 350 indicates the longitudinal direction of the oven 300. 306 is an exhaust duct for flue gases.

However, as most clearly seen in Figures 9 and 10, the oxidant lances 311, 312 are not merely, like the lances 211, angled in the direction of rotation marked by the arrow 351 212 in Figures 4-7, 10 534 084 11 relative to the horizontal plane, but the lances 211, 212 are also angled in the horizontal plane, relative to a longitudinal vertical plane, in a direction of rotation indicated by the arrow 352. This causes the resulting mixture of oxidant and fuel in the V- The shaped space 303 (see Figure 9) between the ingot 301 can be spread even more evenly than is possible only by angling the lances 311, 312 in the horizontal plane as above.

It is preferred to adjust the launch direction of each individual oxidant lance depending on the actual application, so that the resulting temperature distribution in the V-shaped space 303 becomes as homogeneous as possible. It is especially preferred that at least two oxidant lances 311, 312 are mounted so that they open into the furnace space above each other and so that their respective oxidant can flow out into the furnace space and / or the vertical plane. with different angles either in the horizontal plane This results in even distribution of the fuel / oxidant mixture but with the possibility of maintaining a low risk of local overheating due to the added oxidant. It is preferred that the angle in the horizontal plane, in the direction of rotation 352, between the oxidant flow from each individual oxidant lance and the main longitudinal direction of the V-shaped space 303 is 10 ° or less in either direction.

It is especially preferred that at least one lance for oxidant 311, 312, 321, 322, preferably all such lances, are adjustable so that it is possible to angle its respective stream of oxidant in the horizontal plane and / or in the vertical plane, preferably in both horizontal planes. and the vertical plane.

This means that the furnace 300 can be adapted to varying operating conditions with, for example, different numbers and / or different sized ingots 301 to be heated. According to a preferred embodiment, more than one lance for oxidant is used in the furnace, preferably in combination with one and the same lance for fuel, the heating effect in the furnace being regulated during operation by switching one or more lances on or off , while the amount of fuel supplied is controlled to at all times or at least over time stoichiometrically correspond to the oxygen supplied in total by the oxidant. To reduce the total heating effect in the furnace from a certain higher power level to a certain lower power level, an oxidant lance can be operated pulsating, where the on and off periods are varied so that the average delivered power becomes the desired one. In addition or alternatively, one or more oxidant lances can be completely turned off.

In this context, it is preferable to start the heating process with all oxidant lances switched on, the total heating effect being maximum. When the furnace has reached a certain predetermined operating temperature, one or more oxidant lances can either be driven pulsating or switched off.

This reduction of the total heating effect can take place in one or more steps, by changing the number of turned on oxidant lances and / or by changing the time periods of one or more oxidant lances which are driven pulsating.

Thereafter, the total heating effect can be gradually reduced in the same way, while maintaining the operating temperature in the furnace and until the ingot has reached a desired final temperature.

Then the total heating effect can be further reduced, still in the same way as described above, so that the temperature equilibrium prevails during a holding time with a constant casting temperature. Throughout this process, it is preferred that, at all times, at least one oxidant lance be operated at full performance.

It is further preferred that, at all times, at least one oxidant lance, which is the oxidant lance that opens into the furnace of the lances in an assembly comprising at least one fuel lance and at least one oxidant lance, is operated at full performance. It is especially preferred that this at least one oxidant lance is operated at the above-mentioned high launch speeds. In this way, it is possible to regulate the total heating power over a wide power range and at all times ensure adequate convection and thus temperature homogeneity in the entire furnace space, including in the V-shaped space between the ingots.

If a total heating effect is desired which is lower than that obtained when only one oxidant lance is operated at full performance, it is preferred that only one oxidant lance is operated pulsating.

This single oxidant lance in this case is preferably an oxidant lance which constitutes the lowest opening oxidant lance in an assembly comprising at least one fuel lance and at least one oxidant lance, the only lance opening above at least one fuel lance through which fuel is supplied.

To further increase the thermal homogeneity during a process according to the present invention, it is further preferred that oxidant alternately be supplied by different lances for oxidant, or by different constellations of lances for oxidant. Thus, one and the same total heating effect can be maintained but with the use of alternating oxidant lances. This results in temperature equalization over time, and reduces the risk of local overheating in so-called "hot spots". It is especially preferred to convert an existing pit furnace operated by conventional air burners to instead be operated by oxyfuel combustion, by installing one or more fuel lances and one or more oxidant lances operated as described above. Through such a conversion followed by such an operation, an existing pit furnace can be converted in a cost-effective manner to a more environmentally friendly oxyfuel operation without having problems with a lack of thermal homogeneity in the furnace.

Referring again to the pit furnace 200 illustrated in Figures 4-7, it is further preferred to increase the thermal homogeneity of the furnace 200 by providing at least one lance 230 for an oxidant having an oxygen content of at least 85% by weight in a furnace wall, so that the lance opens inside the furnace 200 and so that oxidant can be applied directly to the space 205 with triangular cross-section (see figure 6) which is present under at least one ingot 201 which. is inclined against an inner wall of the pit furnace 200, between the ingot 201 and the wall. The fact that the oxidant can be supplied directly to the space 205 is to be interpreted as meaning that the stream of oxidant originating from the lance 230 flows into the space 205 without encountering any obstacle in the way. Preferably, the lance 230 opens into the space 205 itself, but it can also open some distance outside and push the oxidant stream into the space 205.

In the case where several ingots 201 are present in the furnace 200 along the same furnace wall, this space 205 of triangular cross-section will generally constitute an elongate, substantially cylindrical body of triangular cross-section which is partially separated from the heated part of the furnace 200. When oxyfuel used to heat the furnace 200, it is difficult to achieve a sufficiently high temperature even in the space 205. This problem exists both in the case where one or more ingots 201 are inclined in a row along the same inner wall and in in which case the ingots are inclined towards both opposite long sides, as shown in Figures 4-7.

The height of the bed 202 of scale varies during operation and also over time during several cycles 230, operating cycles. Since oxidant planes 240 which open directly into the space 205 risk falling below the level of the bed 202 when there is a sufficient amount of scale on the furnace floor, it is preferable to arrange all lances which open into the space 205 below the ingot 201 at such a height that it is possible to monitor the scale level and empty the furnace floor of the scale before reaching the level of the installed lance mouths.

It is especially preferred that the oxidant lances 230, 240 be arranged to open at a height above the furnace floor which is above the maximum level of a scale bed which occurs in the furnace during operation. More specifically, it is preferred that they are arranged to open at a height above the oven floor of 0.5-1.0 meters.

It is further preferred that the oxidant from the lance 230, in 212, preferably at at least 100 m / s, similar to that from the lances 211, be supplied at high speed, more preferably at least the speed of sound, preferably at least mach 1.5. With such high launch speeds, the advantages described above are achieved in terms of temperature homogeneity and low flame temperature with accompanying low values for CO and NOK. This is especially important to avoid local overheating in the relatively narrow space 205 below the ingot 201, and also means that the lance 230 can be placed so that it opens further up along the inner wall of the furnace 200 without risking giving rise to local overheating of the ingot 201 at low levels of the scale bed 202. In addition, the launched high velocity stream of oxidant will suck hot furnace gases into the space 205 from surrounding portions of the furnace 200, further increasing the thermal homogeneity of the furnace 200 through to distribute heat energy to the space 205.

The present inventors have discovered that the formation of embers during operation tends to consume large amounts of oxygen.

It has been noted that in some cases this leads to a lack of oxygen in the combustion reaction, whereby the concentration of CO in the furnace atmosphere can increase sharply very quickly. According to a preferred invention, this phenomenon is utilized in that the main combustion, in the main furnace space which consists of the parts of the furnace 200 which does not constitute the space 205, is continuously regulated to be sub-stoichiometric by regulating down the total supplied oxidant by the oxidant lances 211, 212 which open outside the space 205. This thus leads to high levels of CO in the furnace atmosphere. This CO is then oxidized in the space 205 by means of an additional supplied oxidant with at least 85% by weight of oxygen, which is supplied through the oxidant lance 230 to the space 205. With this further oxidation, global stoichiometric equilibrium in the furnace 200 is achieved.

Thus, in this case, no additional fuel is supplied to the space 205. Instead, the oxidant supplied through the lance 230 is caused to react for the most part with CO formed by incomplete combustion of fuel in the furnace 200, by means of oxidant supplied to a part of the furnace which does not consist of the space under the ingot. Thus, the combustion of the fuel takes place in two stages in the furnace 200, namely a first stage when CO is formed and a subsequent stage when complete combustion to CO 2 takes place. An alternative embodiment is shown in Figures 8-10, wherein a separate fuel lance 331 supplies additional fuel, in addition to the fuel supplied through the lances 310, 320 to the V-shaped space 203 and to the remainder of the fuel. the furnace space, to the space 305 (see Figure 9), with which fuel the oxidant supplied by the lance 330 is reacted. In this case, a down-regulation of the supplied oxidant to the rest of the space in the furnace is not required to achieve an understochiometric combustion.

According to a preferred embodiment, more than one lance for oxidant is arranged in the space 205, 305.

Thus, in Figures 4-7, in addition to the lance 230, a corresponding lance 230 is also arranged at the opposite short end of the furnace 200 so that it opens into the space 205 under the ingots 201 which are inclined towards the opposite long side of the furnace. In this case, where at least two ingots 201 as. to be heated are inclined to each of the respective first and second opposite inner walls of the pit furnace 200, so that a respective space 205 of triangular cross-section is formed under each respective ingot, it is generally preferred that at least one respective lance 230, 240 for oxidant with an oxygen content of at least 85% by weight of oxygen is arranged in a respective furnace wall so that it opens inside the furnace 200 and so that oxidant can be supplied to the respective space 205, and that the lances 230, 240 are further arranged to mouth in each opposite oven wall and directed so that the streams of oxidant together give rise to a circulating flow movement in the furnace 200. In Figure 7, the circulating flow movement will thus, starting from the lance 240, run in the direction 250 to the opposite short end, perpendicular to the mouth of the lance 230, then back to the first short side and finally perpendicular back to the mouth of the lance 240. Such a arrangement results in a good heat homogeneity in the entire space 205 under all the ingots arranged in the oven 200.

Figures 8-10 illustrate a corresponding arrangement comprising oxidant lances 330 and 340, respectively. In this case, the preferred but not necessary design is also shown with a respective fuel lance 331, 341 used in combination with each oxidant lance 330, 340.

What has been said above regarding alternating operation with several different oxidant lances for increasing temperature homogeneity applies to 240, 330, 340. It is possible to drive, for example, the lances 230, also operation of the lances 230. Thus, the 240 is alternating, so that first one 230, then the other 240, then again one of the 230 lances is driven, while the lance which is not driven at any time is turned off. It is also possible and preferred to perform such alternating operation including both oxidant lances 230, 240, 330, 340 son opening in the space 205, 305 as well as oxidant lances 211, 212, 221, 222, 311, 312, 321, 322 opening in the space 203, 303. With such an operating mode, the temperature homogeneity can be maximized over time, and local overheating can be avoided, in a way that can be easily adapted to the current operating conditions.

According to a preferred embodiment, the temperature in the oven is measured by means of conventional temperature sensors (not shown) in different places where local overheating can be feared, and the alternating operation is controlled so that the heating effect is reduced in places where the measured temperature is so high that overheating is risked, ie. is higher than a certain predetermined value due to the heated material. 10 15 20 25 30 534 084 19 Due to the above-mentioned concerning the consumption of oxygen in the formation of the scale, in order to control the concentration of CO in the furnace, it is also preferable to measure the oxygen level in the furnace during operation, for example by means of one or more in conventional lambda probes, and to regulate, based on this measured value or these measured values, the amount of oxygen supplied by oxidant planes 240, 330, 340, 205, 305, 211, 212, 221, 222, 311, 321 so that the oxygen concentration is 230, 312, in the oven is kept substantially constant. The control can take place, for example, by continuously controlling the supply of oxidant through one or more oxidant lances or by driving one or more oxidant lances pulsating with suitable ratios between on time and off time. This means partly that the amount of CO in the exhaust gases can be controlled to desired low levels, and partly that a possible afterburning in the space 205, 305 can be optimized.

Preferred embodiments have been described above. However, it will be apparent to those skilled in the art that many changes may be made to the described embodiments without departing from the spirit of the invention.

For example, an oxyfuel combustion according to the present invention can be used as a complement to one or more air burners in a pit furnace, to increase the maximum capacity of the pit furnace or to be able to reduce the effect on the air burners with maintained capacity with less negative environmental consequences.

Furthermore, the lances for oxidant and fuel illustrated in Figures 4-10 can be arranged in other constellations. More oxidant lances can be arranged, for example, to heat particularly inaccessible spaces and / or create additional turbulence in the furnace, depending on the actual operating conditions. The lances of the V-shaped space do not have to be arranged centrally in said space which opens into me, but can for instance be arranged with their respective orifices slightly offset in the horizontal plane. In this position, it is preferred that the resulting downward flow of oxidant intersects through an area to which fuel is supplied in the V-shaped space. In addition, more fuel lances can be used in each unit or group, alternatively in other places in the furnace so that fuel is supplied to a place which is cut by one or more high-speed streams of oxidant.

Finally, it is possible to arrange an oxidant lance at a low height in each of the corners of the furnace, so that oxidant is supplied from both holes into the space under the ingot along both long sides of the furnace.

Therefore, the invention should not be limited by the described embodiments, but may be varied within the scope of the appended claims.

Claims (14)

10 15 20 25 30 534 084 21 P A. T E N T 'K R A V A method of increasing the thermal homogeneity of a pit furnace (200; 300) (201; 30l) is heated to be inclined to each of the respective fronts in which at least two ingots are to stand and other opposite inner walls of the pit furnace (200). ; 300) so that (20l; 301) the ingot forms (203; 303) the ingot an elongate space with V-shaped cross-section between them seen along the first and second wall, characterized in that at least one separate lance (211,2l2,22l , 222; 311, 312, 321, 322) for an oxidant having an oxygen content of at least 85% by weight of oxygen and at least one (210, 220; 310,320) separate lance for fuel is arranged in a (200; 300) from each other and so that oxidant and fuel are brought (203; 303) (211,212,22l, 222: for oxidant are arranged to be (210,220; 310,320) directed so that the oxidant flows obliquely downwards and furnace wall so that they mouths inside the furnace at a distance to be supplied to said V-shaped space and burned there, and by the lance 311, 312, 32l, 322) mouth above the mouth of the fuel lance and along the longitudinal direction of said V-shaped space (2Ö3; 303). A method according to claim 1, characterized in that (211,2l2,22l, 222; 311, 312,32l, 322) is arranged to open above all the supply (210,220; 310,320) of the lance for oxidant seal sites for fuel. arranged in (211, 212,221, 222; 311,312,321, for oxidant is brought to the mouth. the same furnace wall in which the lance 322) 3. A method according to claim 1 or 2, characterized in that the oxidant is applied at a speed of at least 100 m / s. 10 15 20 25 30 534 084 22 4. A method according to claim 3, characterized in that the oxidant is applied at a rate of at least the speed of sound. A method according to any one of the preceding claims, characterized in - (211, 212, 221, 222; (211, 220; 310,320) is brought to be directed so that the respective currents meet in the V-BV 311, 312,221,322) that the lance for oxidant and fuel respectively formed the space (203; 303). Method according to one of the preceding claims, characterized in that the lance (211, 212, 221, 222; 311, 312,221, 322) for oxidant is arranged to be mounted so that the oxidant flows out into the furnace space at an angle of between 0 and 20 ° relative to the horizontal plane. A method according to claim 6, characterized in that the lance (211, 212,22l, 222; 311, 3112,221,322) for oxidant is caused to be mounted so that the oxidant flows out into the oven space at an angle of between 3 and 5 ° in relation to the horizontal plane. 8. A method according to any one of the preceding claims, characterized in that the lance (211, 212, 221, 222; 311, 312, 321) for oxidant is made to be adjustable, so that it is possible to control the angle of its strands1 of oxidant in both the horizontal and vertical planes depending on the operating conditions. A method according to any one of the preceding claims, characterized in that (211, 212,22l, 222; 311, 312,321, 322) that at least two lances for oxidant are caused to be mounted so that they open into the furnace space above each other and so that the lances of the lances (211, 212,22l, 222; 311, 312,32l, 322) can oxidize into the furnace space at different angles in the horizontal plane and / or the vertical plane. 10. A method according to claim 9, characterized in that lances (212,222; 3112,322) for oxidant which open relatively further up are arranged so that the respective oxidant of such lances can flow out into the furnace space at an angle in relation to to the horizontal plane which is equal to or relatively larger compared to oxidant currents from lances (211, 221; 311, 321) which open relatively further down. Method according to Claim 9 or 10, characterized in that (200; 300) operation is caused to be regulated by, on the one hand, one or more lances (211,2l2,22l, 222; 311, 312,32l, 322) of the heating effect in the furnace. during for oxidant it is switched on or off, partly because the amount of added fuel is made to be regulated to stoichiometrically correspond to the oxygen supplied by the oxidant in total. A method according to any one of claims 9-11, characterized in - (200; 300) being further increased during operation by alternating in addition to passing the heat homogeneity in the furnace oxidant through different lances (211, 212,221,222; 311, 312, 321, 322) for oxidant or constellations of oxidant lances. 13. A method according to any one of the preceding claims, characterized in that the oxygen level in the furnace (200; 300), for example by means of one or more lambdason- is caused to be measured, there, and by passing it through. lance 321, 322) (211, 212,221,222; 311, 312, for oxidant-supplied oxygen during operation is controlled so that the oxygen concentration in the furnace (200; 300) is kept substantially constant. A method according to any one of the preceding claims, characterized in - that a first (2110.2l, 212; 3110, 311, 312) of group of lances consisting of at least one lance for oxidant with an oxygen content of at least 85% by weight and at least one lances for fuel are arranged to open in (200; 300), in that a further group of (220,22l, 222; 320,32l, 322) a short side in the furnace lances consisting of at least one lance for oxidant with an oxygen content of at least 85% by weight and at least one lance for fuel are arranged (200; 300), that all lances in the first group are caused to open in an opposite short side of the furnace and arranged to open at a height above the furnace floor which is between 0.9 and 1.5 meters above the level above the furnace floor at which the lowest opening lance j. the second group is caused to open.