AT506950B1 - PROTECTIVE GAS COOLED OXYGEN BLASLANT - Google Patents

Description

Austrian Patent Office AT506 950 B1 2010-01-15

description

PROTECTIVE GAS COOLED OXYGEN BLASLANT

The present invention relates to a protective gas cooled oxygen blowing lance.

In the treatment of steel melts with oxygen from a Sauerstoffblaslanze it is necessary to control the steel quality produced to determine the composition of the molten steel. This can be done by analyzing samples from the molten steel, as well as by analyzing samples of the waste gases produced during the treatment of molten steel. Typically, samples of molten steel are drawn through sublucents other than the oxygen blowing lance. Further information on how to control the treatment with oxygen gives the temperature of the molten steel.

The penetration depth of the oxygen into the molten steel significantly influences the time required for the treatment. Depending on the tear-off behavior of the oxygen flow at the outlet from the outlet nozzles of an oxygen blowing lance, the penetration depth and thus the time expenditure change. Changes in the tear-off behavior are caused, for example, by wear of the outlet nozzles, changes in the distance of the oxygen blowing lance from the molten steel, and changes in the pressure prevailing in the region of the oxygen lance. Information about parameters such as distance from the molten steel, temperature of the molten steel, pressure, are particularly meaningful when measured in the focal spot of the molten steel treatment for use in controlling the treatment process. These parameters are difficult to obtain in the case of water-cooled oxygen blowing lances since sensors for these parameters must enforce the cooling jacket of the oxygen blowing lance, in particular the lance head. This increases the risk of leakage of the cooling jacket. As a water-cooled lance due to the intense cooling of the outer skin of the oxygen lance also exacerbations of freezing slag spatter and steel splash occur, mounted in the outer skin sensors are exposed to the risk of covering by exacerbations.

Water cooling the oxygen blowing lance is a common method of protection against wear. The disadvantage here is that the weight of the oxygen blowing lance is considerably increased in use by the water cooling, which makes correspondingly dimensioned carrying devices necessary and makes the oxygen lance overall lumbering. In addition, there is a risk of leakage of the cooling jacket and associated dangerous cooling water entering the molten steel.

It is known to replace the water cooling by other cooling media. DE10253463 presents a gas-cooled lance. The problem of determining measured quantities in the focal spot for controlling the treatment of steel melts with oxygen is not dealt with in DE10253463.

It is the object of the present invention to provide an oxygen blowing lance, can be determined by sensors at least in the focal spot in the treatment of molten steel without risk of leakage of a water cooling jacket via sensors.

This object is achieved according to the invention by a protective gas-cooled Sauerstoffblaslanze with a central technology channel, and next to the technology channel at least two, preferably three to six, oxygen lines, the lancet head side are each provided with at least one outlet nozzle, wherein the longitudinal axes of the oxygen lines from the longitudinal axis of the technology channel are different, one of the technology channel and the oxygen lines surrounding thermal protection device made of refractory material, which forms the outer skin of the oxygen blowing lance, the spaces between the oxygen lines with outlet nozzles, the technology channel and the thermal protection device with a shielding gas supply device are connected, and the thermal protection device at least one layer, preferably several Layers, refractory material, wherein the oxygen lance comprises at least one sensor for determining measured variables, w obei the sensor at at least one of the points - thermal protection device, - technology channel, - outlet nozzles is mounted so that it can determine in a lance head side forming an extension of the technical channel space measurement quantities.

The oxygen blowing lance according to the invention has a central technology channel, which is adjacent by several, ie at least 2, oxygen lines. Preferably, there are 3 to 6 oxygen lines. The longitudinal axes of the oxygen lines do not coincide with the longitudinal axis of the central technology channel, so they are located next to the technology channel. The oxygen lines are each provided with at least one outlet nozzle on the lance head side; However, one or more oxygen lines may also be provided with a plurality of outlet nozzles.

Compared to an oxygen lance with a single oxygen line, the regulation of the oxygen supply is facilitated by the presence of several oxygen lines, since the individual oxygen lines can be controlled independently of each other. Different amounts of oxygen per unit time can thus be supplied via the different oxygen lines and different pressures of the respectively supplied oxygen can be set. This can influence the movement of the molten steel and the movement of slag on the molten steel. In addition, the oxygen partial pressure in the gas space can be better regulated than when using a single oxygen line.

In the treatment of a molten steel, the oxygen penetrates into the molten steel in the so-called focal spot. Optionally present on the molten steel slag is pushed away by the oxygen jets. The focal spot is located below the oxygen lance on an extension of its longitudinal axis. Since a central technology channel is present in the oxygen blowing lance centrally between the oxygen lines, the focal spot is thus located in an area region forming an extension of the technology channel. By means of probes which can determine measured quantities in a space area forming an extension of the technical channel in the lance head side, measured variables, also called parameters, can be determined from the focal spot. It is particularly advantageous that, since optionally on the molten steel slag is pushed away by the flow of injected oxygen, the view is released to the molten steel. As a result, measured quantities relating to molten steel can be better determined than when sensors are used which are directed to regions of the surface of the molten steel which may be covered by slag. The sensors are attached to at least one of the points - thermal protection device, - technology channel, - outlet nozzles.

In the case of the presence of multiple sensors, one or more sensors may be present at several or all of these locations.

Since no water cooling is present, there is no risk of leakage of a water-supplied cooling jacket.

Therefore, sensors can be attached anywhere on the Sauerstoffblaslanze without having to fear leakage of water cooling in such places. As a result, sensors can be placed exactly where highly meaningful measurement data can be obtained. For example, information about the gas pressure at the outlet nozzles is particularly important. Advantageously, sensors are also mounted on the oxygen lance, which can determine measured quantities outside the lancet head side of an extension of the technical chamber area forming the technical area.

Likewise, the risk of Verbärun conditions of the outer skin of the oxygen blowing lance or of sensors by freezing slag spatter or steel spatter is reduced due to the lack of water cooling, since the outer skin is less strongly cooled compared to a water-cooled outer skin.

Technology channel and oxygen channels are surrounded in the longitudinal direction of a Thermoschutzvor-direction of refractory material, which forms the outer skin of the oxygen blowing lance. The thermal protection device comprises at least one layer of refractory material. It preferably comprises several layers of refractory material, as this leads to an improved wear resistance. The layers may consist of the same or different refractory material.

Refractory material is to be understood as meaning materials which have high mechanical strength, dimensional stability, wear resistance and corrosion resistance in the conditions prevailing in the treatment of a steel melt of crude steel. These conditions are characterized by temperatures of 20 ° C to 2000 ° C, splashes of acidic to basic slag, splashes of liquid metal. The refractory material is, for example, silicate ceramics such as steatite, cordierite and mullite, oxide ceramics as single-substance ceramics such as alumina, magnesia, zirconia, partially stabilized zirconia and fully stabilized zirconia, titania oxide ceramics as a multi-substance system such as aluminum titanate dispersion ceramics such as zirconia-reinforced alumina - Oxide ceramics such as spinel - non-oxide ceramics. Non-oxide ceramics include ceramic materials based on compounds of boron, carbon, nitrogen and silicon.

Preferred non-oxide ceramics are silicon carbide, silicon nitride, aluminum nitride, boron carbide and boron nitride. - Fiber-ceramic composite materials such as metal matrix composites, C / C, C / SiC, SiC / SiC and Al2O3 / Al2O3, Al203 / Zr0, Al203 / SiO2.

The refractory material may also be graphite or boron nitride. When the outer skin of the oxygen blowing lance is surrounded by a protective gas mantle in the treatment of molten steel, there is no risk of oxidation of the graphite or boron nitride under the conditions prevailing in the treatment of steel melts.

Gaps between the oxygen lines with outlet nozzles, engineering channel, and thermal protection device are connected to a shielding gas supply device. Suitable inert gas is any gas which is inert under the conditions prevailing in the treatment of molten steel with oxygen. Preferred is the use of nitrogen or argon.

The protective gas supply device is, for example, a pipe connecting the interspaces with a protective gas reservoir, are present in the devices for controlling the gas flow. During operation of the oxygen blowing lance, the protective gas flows through the intermediate spaces, thereby dissipating heat and thereby cooling the oxygen blowing lance. Furthermore, oxidizing wear of the oxygen blasting lance parts is prevented by the protective gas atmosphere. In addition, the protective gas protects the parts of the oxygen blowing lance which it surrounds from reactions with the environment, such as slag or steel splashes, dusts in the gas space above the molten steel, or gases. In addition, a heat transfer of hot gases from the environment by convection is disturbed by the flowing inert gas atmosphere on the oxygen blowing.

The measured quantities preferably originate from the group from the group - temperature, - gas pressure, - distance of the oxygen blowing lance to solids and / or liquid levels of the slag and / or molten steel, - spectral data.

The temperature can be measured for example in the following ways: - Measurement with a NTC or PTC resistor - Measurement with a temperature-dependent constant current source - Measurement with a thermocouple - Measurement with frequency-analog temperature sensors - Measurement with radiation thermometer such as line scanner infrared cameras, infrared measurement system - acoustic gas temperature measurement.

The temperature of the molten steel gives information about the state of treatment of molten steel that can be used to control the treatment with oxygen.

The gas pressure can be measured, for example, barometrically or manometrically. Knowledge of the gas pressure allows conclusions to be drawn about the tearing behavior of the oxygen as it exits the outlet nozzles, which can be used to control the penetration of oxygen.

The distance of the oxygen blowing lance to solids and / or liquid levels of slag or molten steel can be measured for example by means of: - laser triangulation, - transit time method such as laser radar, - interferonnetrisch operating systems, such as laser interferometer, - magnetostrictive sensors, - ultrasound.

The measurement of the distance of the oxygen blowing lance from the liquid level of the molten steel, or optionally present slag, can be used to control the penetration depth of the oxygen, and thus the treatment time of the molten steel. The control of the penetration depth of the oxygen can be done, for example, by moving the oxygen blowing lance up and down. By measuring the distance can be maintained at any time a distance of the oxygen blowing lance from the liquid level, in which the fermentation of Sauerstoffblaslanze is kept low by metal and slag spatter. Furthermore, a measurement of the distance to solids allows avoiding damage to the oxygen blowing lance by contact with, for example, standing in the molten steel scrap parts that have not yet melted.

Spectral data can be measured, for example, by means of - emission spectral analysis, for example with discharge plasma, with laser-induced plasma or with laser ablation and discharge plasma, - laser-induced plasma spectroscopy,

Spectral data on the composition of the molten steel can provide information about the progress of the treatment of molten steel.

Preferably, in the technology channel, a device for the removal of steel and / or gas samples can be introduced.

Such a device may comprise, for example, a fixed to a metal wire vacuum glass, or a retractable from the technical channel pipe section. In this case, the use of a sublance for sampling can be dispensed with. It is advantageous that can be scooped up directly from the molten steel during the removal of steel samples in the focal spot and no possibly present on the molten steel slag layer must be penetrated.

Preferably, a device for measuring temperature and / or composition of a removed steel or gas sample can be introduced into the technology channel. In this case, the samples can be evaluated without delays due to removal from the oxygen blowing lance. Such an evaluation can be made, for example, by laser-induced plasma spectroscopy.

Compared to a detection of parameters of the molten metal from the focal spot and thus from the moving melt - a measurement of a sample taken in the technical channel has the advantage that the sample is not moved in the technology channel. In addition, when measuring in the technical channel also other, caused by the environment of the focal spot, the measurement influencing disturbing factors such as changing ambient pressures and poor visual conditions. In addition, a detection of parameters of the molten steel in the technical channel has the advantage that the sample does not have to be taken from the oxygen blowing lance according to the invention in order to arrive at the parameters. This makes the capture faster.

According to one embodiment, a device for acquiring spectral data can be introduced into the technology channel.

According to an advantageous embodiment of the technology channel is connected to a device for the supply of solid, liquid or gaseous substances. By adding, for example, alloying substance-containing substances to molten steel by such a delivery device, the quality of the steel obtained can be influenced. If the addition can be made via the technology channel, no additional channels for this purpose have to be provided in the oxygen blowing lance, or the addition via additional lances can be reduced or rendered obsolete.

The thermal protection device surrounds the technology channel and the oxygen lines at least in the longitudinal direction of the oxygen blowing lance. Advantageously, the thermal protection device is traversed by channels, which channels are connected to a protective gas supply device and open into the space between the oxygen lines with outlet nozzles, the technology channel and the thermal protection device and / or have one or more orifices in the outer skin of the oxygen blowing lance. In this case, the shielding gas better contributes to cooling and protection of the thermal protection device from oxidative wear. If channels have an orifice in the outer skin of the oxygen blowing lance, this is enveloped by a protective gas jacket, which is a particularly effective protection against exacerbations and wear. Slag or metal splashes can be blown away from the protective gas flow before contact with the outer skin and in this case do not reach the outer skin. Slag or metal splashes that reach the outer skin can be partially blown off again by the protective gas flow. Since the outer skin is not water cooled, these splashes freeze slowly, which facilitates blowing off. Slag or steel splashes impinging on the outer skin cool when passing through the protective gas jacket and strike the outer skin at a lower temperature than an oxygen blowing lance without a protective gas jacket. As a result, reactions with the outer skin are less severe or not at all, so that it is less worn. To-sessile results in the advantage that such resulting decompositions adhere to the outer skin less strong than exacerbations that arise under vigorous reaction with the material of the outer skin. Accordingly, they formerly fall from the outer skin under their own weight as more strongly adhering verbs.

According to an advantageous embodiment, the lance head of the oxygen lance is also covered by the thermal protection device, wherein the lanzenkopfseitige part of the thermal protection device is designed as a protective element which is detachably and replaceably attached to the technology channel, wherein in the protective element passages are present through which the Outlet nozzles are guided to the outside, wherein these passages are each dimensioned so that between the outlet nozzle and the protective element remains a gap. Protective gas can escape through this gap. As a result, the outlet nozzles are protected from exfoliation and wear and cooled. In addition, the protective gas forms a jacket of the exiting oxygen stream, whereby this directed can penetrate into the molten steel. This allows better control of the penetration depth. In principle, the thermal protection device may consist of one or more elements. Advantageously, it consists of several elements, since they are smaller and thus easier to manufacture compared to a single element or can be replaced easier in case of maintenance. For example, the thermal protection device may consist of several stacked rings. Advantageously, at least one element of the thermal protection device is attached to the technology channel. If the element of the thermal protection device, which is at the lowest position when the oxygen blowing lance is in the vertical position - with the lance head at the bottom - is fastened to the technology channel, the load of the elements arranged above it can be carried by this element or its attachment. In such a case can be waived partially or completely to separate fasteners for the remaining elements of the thermal protection device in the oxygen blowing lance, which makes the design and manufacture of the oxygen blowing lance easier.

According to one embodiment of the oxygen blowing lance according to the invention, the length of the technology channel is independent of the oxygen channels and the thermal protection device adjustable. For this purpose, for example, a lance-head-side end portion of the technology channel may include a pipe section, which is in and out of the technical channel. In the extended state of the pipe section extends the technology channel. As a result, measured variables can be determined in different positions without having to move the rest of the oxygen blowing lance.

By means of the oxygen blowing lance according to the invention, measured variables relevant for the treatment of a molten steel can be measured simply and without risk at the positions which are ideal for the respective measured variables. This simplifies the optimization of the treatment.

The present invention will be explained in more detail with reference to the following schematic exemplary figures.

FIG. 1 shows a longitudinal section through the lance head end section of an embodiment of the oxygen blowing lance according to the invention. FIG. 2 shows an oblique view of the lance-head end section of an embodiment of the oxygen blowing lance according to the invention.

FIG. 1 shows a longitudinal section through the lance-head-side end section of an embodiment of the oxygen blowing lance 1 according to the invention. A central technology channel 2 is surrounded by two oxygen lines 3. The outer skin of the oxygen blowing lance is formed by a multi-element thermal protection device 4 made of refractory material. The elements are a tube 4a and a bowl-shaped protective element 4b covering the lance head. The tube 4a is fastened via fastening device 5 on the technology channel. The protective element 4b is fastened via fastening device 6 on the technology channel. Oxygen is shown with wavy arrows. Shielding gas is shown with straight arrows. Shielding gas flows through the spaces between the technology channel 2, oxygen lines 3, and the elements of the thermal protection device 4a and 4b, as well as channels in the tube 4a. The connection of the spaces or the channels with a protective gas supply device is not shown.

The protective gas exits from the channels in the tube 4a, inter alia, on the outer skin of the oxygen blowing lance and envelops them with a protective gas jacket. The oxygen streams emerging from the outlet nozzles 7 are enveloped by protective gas streams emerging from the gaps between the outlet nozzles 7 and the protective element 4b. From openings 17 in the protective element also flows from protective gas. In the technology channel 2, a device for removing steel samples 8 is introduced. For sampling, this is lowered from the technology channel into the molten steel. A sensor for determining the temperature 9 and a sensor for determining the distance of the lance to a solid and / or liquid level 10 are mounted in the technology channel. They record the corresponding measurement data in the area of the lance head that forms an extension of the technical channel. At the 6/11 > Austrian Patent Office AT506 950 B1 2010-01-15

Outer skin of the oxygen lance is attached a sensor for measuring gas pressure 11. Another sensor for measuring gas pressure 12 is attached to an outlet nozzle 7.

For clarity, was on the representation of peripheral edges of the openings 17, the mouths of the channels of the tube 4a, the lower ends of the oxygen lines 3, the lower end of the technology channel 2, the outlet nozzles 7, and the passages of the protective element 4b, through which the outlet nozzles 7 are guided to the outside, omitted.

FIG. 2 shows an oblique view of the lance head end section of an embodiment of the oxygen blowing lance according to the invention, in which the protective element 4b is pulled higher in comparison to FIG. At several points of the outer skin sensors 13, 14, 15, 16 are attached. FIG. 2 also shows a central technology channel 2 and a plurality of outlet nozzles 7 on the lance head. Between the protective element 4b and the outlet nozzles 7 and the technology channel 2 are annular gaps. Furthermore, the protective element 4b has through openings 17 through which protective gas can flow from the interstices between the technology channel 2, not shown oxygen lines, and the elements of the thermal protection device 4a and 4b to the outer skin of the oxygen lance. 1 oxygen blowing lance 2 technology channel 3 oxygen line 4 thermal protection device 4a tube 4b protective element 5 fastening device 6 fastening device 7 outlet nozzles 8 device for taking steel samples 9 sensor for determining the temperature 10 sensor for determining the distance of the lance to a solid and / or

Liquid level 10 11

Sensor for measuring gas pressure

Sensor for measuring gas pressure 12 13 14 15

Sensor Sensor Sensor Sensor 16 Opening (in the protection element) 7/11

Claims (12)

Austrian patent office AT506 950B1 2010-01-15 1. Protective gas cooled Sauerstoffblaslanze (1) with a central technology channel (2), and next to the technology channel at least two oxygen lines (3), the lance head side are each provided with at least one outlet nozzle (7), wherein the longitudinal axes of the oxygen lines are different from the longitudinal axis of the technology channel, a refractory material thermal protection device (4) surrounding the engineering channel and the oxygen lines forming the outer skin of the oxygen blowing lance (1), the spaces between the oxygen lines (3) with outlet nozzles (3) 7), the technology channel (2) and the thermal protection device (4) are connected to a protective gas supply device, and the thermal protection device (4) at least one layer, preferably a plurality of layers, refractory material, wherein the oxygen lance (1) at least one sensor (9,10 , 12) for determining measured quantities, wherein the sensor is mounted on at least one of the points - thermal protection device (4), - technology channel (2), - outlet nozzles (7) so that it can determine measured quantities in a spatial region forming a length of the technical channel on the lance head side. 2. oxygen blowing lance according to claim 1, characterized in that the measured variable from the group - temperature, - gas pressure, - distance of the lance to solids and / or liquid level, - spectral data comes. 3. oxygen blowing lance according to any one of the preceding claims, characterized in that in the technical channel (2) a device for removing steel and / or gas samples (8) can be introduced. 4. oxygen blowing lance according to claim 3, characterized in that in the technical channel (2), a device for measuring temperature and / or composition of a withdrawn steel or gas sample can be introduced. 5. oxygen blowing lance according to any one of the preceding claims, characterized in that in the technical channel (2) a device for detecting spectral data can be introduced. 6. oxygen blowing lance according to any one of the preceding claims, characterized in that the technology channel (2) is connected to a device for supplying solid, liquid or gaseous substances. 7. oxygen blowing lance according to any one of the preceding claims, characterized in that the thermal protection device (4) is crossed by channels, wherein the channels are connected to a protective gas supply device and open into the space between the oxygen lines with outlet nozzles, the technology channel and the thermal protection device and / or Have mouths in the outer skin of the oxygen blowing lance. 8. Sauerstoffblaslanze according to any one of the preceding claims, characterized in that the lance head of the oxygen lance is also covered by the thermal protection device (4), wherein the lanzenkopfseitige part of the thermal protection device (4) as a protective element (4 b) is formed, the detachable and interchangeable on Technical channel (2) is fixed, wherein in the protective element passages are provided through which the outlet nozzles (7) are guided to the outside, said passages are each dimensioned so that between Outlet nozzle and protective element remains a gap. 9. oxygen blowing lance according to any one of the preceding claims, characterized in that the thermal protection device (4) consists of several elements. 10. Sauerstoffblaslanze according to claim 8, characterized in that at least one element of the thermal protection device (4) on the technology channel (2) is attached. 11. Sauerstoffblaslanze according to any one of the preceding claims, characterized in that at the Sauerstoffblaslanze also sensors (11,13,14,15) are mounted, which can determine the measured distance from the lanzenkopfseitig an extension of the technical channel forming space area. 12. Use of an oxygen blowing lance according to one of the preceding claims for the oxygen treatment of steel melts. For this 2 sheets drawings 9/11