This invention corresponds to the metallurgical domain, specifically the field of the melting of ferrous and non-ferrous alloys, steel melting, and metallurgical processes that involve the addition of pulverized alloy elements heated to temperatures above 400° C. to be used for incorporation in liquid metal streams, with the aim of adjusting its chemical composition or undertaking some treatment of the liquid metal.
Currently there are no volumetric or gravimetric dosing devices on the market that provide controlled massic or volumetric flows of particles at temperatures above 400° C., since at these temperatures, particles tend to congregate and sinter. Additionally, the conditions for heat corrosion and thermal fatigue in the components of dosing devices require the use of special materials for their manufacturing such that they resist these conditions. Nevertheless, and in spite of the use of sophisticated materials such as superalloys in the manufacturing of the components of dosing devices that operate at high temperatures, the aforementioned adverse conditions shorten their service lives, making them unviable for commercialization.
Different state-of-the-art strategies have been used to resolve these problems, such as heating a flow of particles whose output has already been controlled by volumetric or gravimetric dosing device, which then falls into a reaction chamber. Said current of particles can be heated by different means, such as for example by using overheated gases in a plasma state, or a high-powered laser energy source. A gas vector can also be used to direct the current of particles towards a fluidized bed reactor where the particles are heated. In the inventors' opinion, all these solutions are complex and costly. In the state of the art, patents U.S. Pat. No. 6,994,894, EP 788,987, U.S. Pat. No. 5,738,249, US 2012/027441, and U.S. Pat. No. 7,252,120 describe examples of devices and procedures for heating particles after a dosing device, before a dosing device, and conventional dosing devices for particles at room temperature. The text of said documents is incorporated into this document as background.
As a consequence, with this invention a process and device are provided with which the problems expressed above are avoided. The invention presented below is composed of a heated chamber with one or more gas burners, where a current of particles is received that is added manually or via a massic or volumetric flow controlled by a gravimetric or volumetric dosing device that operates at room temperature and is located somewhere above the chamber. These particles are heated by radiation from the walls of the chamber and the flames of the burners or by convection via the hot gases of combustion during their flight when inside the chamber, reaching the required temperature.
The process and device that constitute the invention avoid the problems stated earlier. The device is composed of a heated chamber with one or more gas burners, where a current of particles is received that is manually added or added via a pre-established massic or volumetric flow from a gravimetric or volumetric dosing device that operates at room temperature and is located somewhere above the chamber. These particles are heated by the radiation of the walls of the chamber and the flames of the burners and also by convection from the hot gases from combustion during their flight while they are inside the chamber, such that by controlling the residence time in the chamber, when they have finished passing through the chamber they have reached the required temperature.
The device permits heating a current of solid alloy particles, controlled with respect to their volumetric or massic flow and particle size, which fall by gravity into a region adjacent to the wall of the chamber, which is made of refractory material or another material that is resistant to high temperatures that is heated with burners, such that the heating of the particles is performed via the transfer of heat by radiation from the walls of the chamber and by convection and radiation from the flame towards the particles during their residence time in the chamber, in a reducing or oxidizing atmosphere, which constitutes the essential principle of the process.
The device is composed of a cylindrical chamber with a truncated cone-shaped end made out of refractory material or another material that is resistant to high temperatures, where there are one or more burners directed tangentially at the wall and pointed downward, with their flames at a predetermined angle between 0° and 45° from horizontal, such that depending on the angle and the volumetric input and nature of the combustion gases that enter via the burners, the particles reach a certain temperature as they leave the device. The angle used and the gaseous volumetric flow introduced establish the trajectory and the residence time of the flames of the burners and the particles that are swept along by these flames into the preheating chamber. A low angle and the use of low volumetric flows of gases introduced into the burners causes a greater residence time for the flames and particles in the chamber. The use of greater volumetric flows of gases used in the flame brings greater thermal energy into the chamber, but it reduces the residence time of the particles. The reducing or oxidizing nature of the gases used to operate the system depends on the mix of combustible gas such as natural gas, LP gas, or any other type of combustible gas that is combined with oxygen, whether from a pressurized air current or air that is enriched with oxygen, and the proportions used determine the calorific value that the flames obtain, which in turn establishes the maximum temperature that the flames reach, the maximum temperature to which the particle preheating chamber can be heated, and the temperature that the particles reach upon leaving the system. The adequate balance of the currents used of air containing oxygen or oxygen and combustible gas, which can be achieved by any expert in burners, allows for obtaining an appropriate mix with the greatest calorific power and a reducing or oxidizing nature as required.
Most of the combustion gases rise in the central region of the chamber towards the upper part of the area, where they are evacuated out of the chamber. Once the internal surface of the chamber has reached an adequate temperature, above 950° C. as measured via thermal sensors, the temperature at which it has been experimentally confirmed that it emits an amount of radiation sufficient to heat the alloy particles of the type and size of interest for this application to temperatures above 400° C. as required, a controlled massic or volumetric flow of alloy particles with a pre-established particle size with average diameter of between 0.1 mm and 8 mm, and especially particles with an average diameter between 0.3 and 3 mm, is introduced in a region adjacent to its vertical walls coining from manual feeding or from a gravimetric or volumetric dosing device, such that during the time it spends within the chamber, these particles are heated by the radiation coining from the walls of the chamber and the flames of the gas burners, and also by convection mechanism of the hot combustion gases in contact with the particles while they are swept along by the combustion gases following a circular descending trajectory, sticking closely to the walls of the chamber, until upon their arrival at the bottom the particles continue their descending trajectory while the combustion gases are directed along the symmetry axis of the cylindrical chamber and up, leaving the device.
The device was tested at the Industrial Plant in order to corroborate the functioning of the particle dosing device system at high temperature, for which the device was constructed using a metallic support structure, a metal shell to support its components, and a moldable refractory material to work at high temperatures.
Said device is shown in
In order to heat the chamber, two gas burners were used, with the mouths where the flames come out located tangentially with respect to the wall of the chamber and directed downward forming a 15° angle from horizontal and fed with natural gas and compressed air. The implementation of the system can be seen in
Preliminary measurements were made of the heating of the chamber using different angles and combustion mixes, as illustrated in
In
The alloy particles of interest for this invention include high density alloy particles such as particles of copper, nickel, ferrochrome, ferromolybdenum, ferrovanadium, and all particles that are alloys or used for treating liquid metal with apparent densities greater than 5 gr/cm3, as well as low-density alloy particles such as particles of graphite, ferrosilicon, and all particles that are alloys or used for treating liquid metal with apparent densities less than 5 gr/cm3.
With the aim of verifying the effectiveness of the device that is the object of this invention with high and low density alloy particles, heating tests were carried out with copper particles (apparent density of 8.9 gr/cm3) and with particles of 75% ferrosilicon, Fe-75% Si (apparent density of 3.7 gr/cm3). A pre-established amount of 600 grains of the particles was weighed out in the case of copper and 300 grams in the case of Fe-75% Si, which were added at room temperature via a steel duct equipped with a funnel on top, in an area next to the wall of the chamber, as illustrated in
Upon analyzing
The results obtained suggest that according to the process conditions and the nature of the particles, it is possible to reach temperatures above 400° C. for alloy particles heated via the proposed device, which is something that is unprecedented to date.
Finally, it is important to emphasize that experiments were also performed reaching the same initial temperature in the walls of the chamber, but turning off the burners during the addition of the particles, in which case, the particles only heated up at the beginning, which suggests that the fluid dynamics of the combustion gases that sweep the particles along during their flight inside the chamber and the process variables that determine said dynamics are responsible for the temperatures achieved by the alloy particles as they leave the device at its exit.
Number | Date | Country | Kind |
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MX/A/2015/010258 | Aug 2015 | MX | national |