DE2953669C1 - Pump for gas-dynamic mixing of liquid metal - Google Patents

Description

The present invention relates to a pump for gas-dynamic mixing of liquid metal when melting directly in the tank of melting furnaces, in most cases the melting process is accelerated.

By US-PS 40 08 884 is a pump for gas-dynamic Mixing of liquid metal has become known, in which a pipe in a molten metal immersed. The end of the tube lying outside the container is provided with means for feeding a Pulse of pressurized gas and connected to create a vacuum. Through the opening of the in the melt lying end of the tube, the liquid metal flows parallel to the surface of the melt in the container.

A similar arrangement has become known from DE-OS 28 37 510. Funds are provided there to the effect of the vacuum immediately before a pressure gas pulse is fed into the pipe of the pump to ensure the free fall of the raised metal position under the action of gravity to cancel.

The known pumps enable the performance of the melting furnace to be increased; thus exhaust themselves however, not all of the possibilities that are inherent in the present designs. So z. B. the removal (suction) of the metal in the tube is realized in one and the same place, and the metal is practically in one of these Steep close zone ejected, whereby the heat and mass transfer / wipe the upper and the lower metal layers in the bath are not sufficiently effective, which is especially true in large-scale smelting units with a significant tub depth is where the temperature difference between the layers mentioned reached a quite significant size. To increase the effectiveness of this In the process, the speed at which the metal flows out of the pump is usually increased. That is, however, with a further increase in the coefficient of energy transfer from the pressurized gas the liquid metal connected, which of course has certain limits, predominantly due to the increase in the Gas saturation and slag formation at the boundary / between metal and gas medium are limited. It's difficult to make use of this factor

ίο a substantial increase in the effectiveness of the mixing to reach. Nor is it always expedient to take the route of increasing the number of pumps To walk in a melting furnace, because this makes operation more difficult and increases gas consumption will; in addition, it is sometimes difficult to achieve from a constructive point of view.

One must point out that the effectiveness of the melting process, the quality of the metal to be produced and the fuel consumption in the furnace on the degree of intensity of the process of heat and Mass exchange between the upper heated and the lower cooled metal layers is dependent. One can see the intensity of the heat and material exchange in the furnace of a directional furnace Increase the flow of the metal in the vertical direction. The existing types of gas dynamic pumps make this possible but not that. As can be seen from the above analysis, occur when the pumps are operated for gas-dynamic mixing of metal

jo difficulties by eliminating them allowed becomes, the effectiveness of the mixing of metal during the melting of the same in the tub of a Increase furnace.

At the moment the problem is energy saving

j5 has become very relevant. Therefore there will be another increase the performance of the melting units through the implementation of a complete and rapid heating and mass transfer in the pan of the furnace contribute to a significant degree in solving this problem. In addition to saving fuel, this also results in an improvement in the quality of the alloys to be produced achieved in terms of the homogeneity of the chemical composition.

The invention is based on the object of a pump for gas-dynamic mixing of liquid metal in a container, in which a pipe is inserted into the melt immersed, the end of the tube lying outside the container with devices for generating a vacuum is connected and through the opening of the tube lying in the melt the liquid metal is parallel to the Surface of the melt in the container flows, to improve so that a complete heat and mass transfer between the upper and lower layers of the molten metal takes place, the performance of the melting furnace is increased, the quality of the metal is improved and fuel is saved.

This object is achieved according to the invention in that the upper wall of the lying in the melt Section of the pipe is thickened and at least one

fao NEN canal, which is tangential into the cavity of the Tube opens and its inlet opening enables a flow parallel to the surface of the melt. Such a structural design of the pump allows a circular flow of the metal in the vertical direction to create; consequently there is a constant confluence of the upper, more heated metal layers with the lower less heated metal layers in the tub instead, resulting in a more intense

Mixing of the metal and rapid temperature equalization over the entire volume of the Tub of furnace leads. The tangential entry of the additional channel, its exit section in the direction of movement of the metal when ejecting it is directed, it allows the flow effect to Suction of the upper metal layers from the tub through the additional channel into the cavity of the pipe using the pump to mix the upper metal layers with the lower metal layers and these to eject together into the tub.

The lower thickened section of the tube, which has additional channels, is expediently in Executed in the form of a removable attachment.

This makes production of the pump are agreed i ^r, fanned and facilitates the cleaning of the channels when grown together with slag during operation of the pump.

The additional channels in the wall of the pipe are preferably at different levels executed relative to each other and above the outlet section of the cavity of the tube.

Such a design of the pump makes it possible for the zone to be effectively mixed with the metal expand. This is particularly important when using the pump in large-scale furnaces with a significant Tub depth.

To explain the invention, an exemplary embodiment is described below with reference to the drawings described. It shows jo

F i g. 1 shows a pump according to the invention and part of a furnace in vertical section along the longitudinal axis;

F i g. 2 shows a section along line 11-11 in FIG. 1.

The direction of movement of the metal during the displacement (by the gas pulse) is indicated by arrows.

H - amount of change in the level of metal in the cavity of the pipe during operation of the pump.

Preferred embodiment of the invention.

The pump for gas-dynamic mixing of liquid metal 1 in the tub of a furnace 2 consists from a lined with a refractory material pipe 3 with a cavity 4 and a removable one Lid 5. The cavity 4 is through a hole 6 in the wall of the tube 3 with a system 7 for Supply of a pulse of pressurized gas and line-connected to a system 8 for generating the vacuum. The control circuit of these systems is conditionally not shown because it is a known one Pump can be borrowed.

The upper wall of the tube 3 immersed in the melt is thickened and has at least one additional wall Channel 10 on. The channel 10 opens tangentially into the cavity 4 v> via a tangential inlet 9 of the pipe 3. The outlet end of the channel 10 enables the melt to flow horizontally.

Several extraction channels 10 can be provided; they are at different heights arranged above the outlet section of the cavity 4 eo of the tube 3. The pipe 3 of the pump has a wall that ends with a thickened lower portion which is in the form of a removable attachment 11 (Fig. 2) is formed, in which additional channels 10 are housed. Such a design μ the pump from individual blocks facilitates the manufacture of the pump and during operation of the same cleaning the channels 10 and cavity 4.

In principle, an embodiment is possible in which each additional channel 10 is arranged in a single detachable attachment.

With a minimum permissible level of the metal 1 (Fig. 1) in the pan of the furnace 2. when the tangential entry 9 of the channel 10 is covered by the metal which connects the channel to the cavity 4, the system 8 is switched on to generate the vacuum.

Under the effect of the vacuum, the liquid metal in the tube 3 rises to the maximum height H and a signal is then given by a transmitter (not shown in the figure) for the response of the system 7 for supplying a pulse of pressurized gas. As a result of the pressure gas pulse, the liquid metal is ejected from the cavity 4 into the trough of the furnace 2 at a predetermined speed. In doing so, the metal is moved in the cavity 4, and it takes some of the metal with it from the additional channels 10, after which these pieces of metal are ejected into the trough of the furnace 2 together with the metal contained in the cavity 4.

The operation of the pump according to the invention is based on the flow effect, i. H. by the presence The frictional forces between the layers of liquid metal separate one jet from the other carried away. The higher the speed of movement of the metal in the cavity 4, the greater it is Metal parts, which are taken from the upper layers of the pan of the furnace 2 via the additional channel 10 will. This creates a circular movement of the metal in the vertical plane, which becomes an intense Heat and mass transfer between the upper and lower metal layers in the tub of the Furnace 2 contributes. Then the liquid metal is again sucked into the pipe 3, and the working cycle repeats itself in the same sequence until a complete temperature equalization is established throughout Volume of the pan of the furnace 2.

The tests carried out on the pump have demonstrated its effectiveness, with the one according to the invention Pump allows, in comparison to the pumps of known design, the necessary for the mixing Reduce time by 10% to 15%.

The pump according to the invention can be used in melting furnaces and vacuum units to increase performance Improving the quality of the metal and reducing the specific fuel consumption.

1 sheet of drawings

- Blank page

Claims (3)

Patent claims: 1. Pump for gas-dynamic mixing of liquid metal in a container with a Tube immersed in the melt, the end of the tube lying outside the container with facilities for supplying a pulse of pressurized gas and connected to devices for generating a vacuum and through the opening of the tube located in the melt, the liquid metal is parallel to the Surface of the melt in the container flows, d a characterized in that the upper wall of the section of the pipe (3) lying in the melt is thickened and at least one channel (10) has, which opens tangentially into the cavity (4) of the tube and its inlet opening a Allows flow parallel to the surface of the melt. 2. Pump according to claim 1, characterized in that the lower thickened portion of the tube (3), which has additional channels (10), is designed in the form of a removable attachment (11). 3. Pump according to claim 1, characterized in that the additional channels (10) in the wall of the pipe (3) at different levels relative to one another and above the outlet section of the cavity (4) of the tube (3) are executed.