WO2007065651A1

WO2007065651A1 - Method for adaptively controlling processes for the production of cast iron

Info

Publication number: WO2007065651A1
Application number: PCT/EP2006/011705
Authority: WO
Inventors: Manfred Fengler
Original assignee: Daimler Ag
Priority date: 2005-12-08
Filing date: 2006-12-06
Publication date: 2007-06-14
Also published as: DE102005058532A1; EP1957219B1; DE502006007242D1; EP1957219B8; EP1957219A1; DE102005058532B4; US20080302503A1

Abstract

The aim of the invention is to be able to produce directly cast GGV and GGG melts in a single-stage process, simultaneously determine the physical and mechanical parameters such as the strength index and the pipe index by means of a thermal analysis and a mathematical evaluation model, continuously compare the process data to the target data with the aid of the process control computer, optimally determine the amounts to be added, and introduce the determined amount into the melt.

Description

Adaptive process control process for the

Manufacture of cast iron

The invention relates to a method for adaptable process control for the production of cast iron, in particular GJV and GJS, and for calculating the addition quantities in melts, in particular iron melts, into which an alloy is introduced, which contains at least magnesium and a further metal as a treatment agent and a vaccine contains.

It is already known (DE19916234C2) to use a cored wire (wire injection) for the treatment of melts, in particular iron or steel melts, by means of wire injection. The filler wire consists of an outer jacket made of metal and a filler material, the filler material having at least a first powdery or granular treatment agent and a second treatment agent. In order to provide a filler wire, in which a uniform distribution of the treatment agents over the length of the filler wire is guaranteed in each case and separation can be reliably prevented, the invention provides that the second treatment agent is in the form of at least one solid inner wire made of solid material. In one embodiment, the jacket is made of steel. However, the jacket can also consist of other materials, in particular Cu or aluminum, and therefore also of the material of the melt to be treated. The first or second treatment agent and / or the coating can have calcium, lead, sulfur, tellurium, boron, carbon, chromium, manganese, magnesium, silicon, niobium, titanium, vanadium, iron or zirconium and / or alloys of these elements and / or compounds with further elements. In the known method, two-stage treatment methods and thus very long process times with the corrections associated therewith are required, since the treatment of the molten metal, hereinafter referred to as the melt, is essentially upstream and the treatment of the melt takes place in the transport pan and then with the aid of wire injection in the casting furnace . There are also high losses in use of the automatic molding machines. Furthermore, corrections are necessary in this two-stage, very long production process and therefore the temperature losses and the consumption of treatment agents are also very high.

The invention has for its object to achieve the production of directly castable GJV and GJS melts in a one-step process and for this purpose to optimally adjust the physical characteristics and the cavity index of the castings within the specified process limits, the condition of the iron being continuously evaluated and the exact amounts added are automatically calculated in order to be able to enter the determined quantity into the melt.

According to the invention, the object is achieved by (1) the following process steps:

1.1 First, the weight of the entire melt and the amount of base iron to be added is determined,

1.2 then the state of the melt is determined using thermal and chemical analysis and the expected physical, mechanical parameters, Strength index as well as the void cortex-x,

1.3 the shaping agents to be introduced into the melt, such as treatment agents, inoculants, alloying agents, carburizing agents, covering material, are then calculated,

1.4 the forming agent with the upper and lower release agents is introduced between the melt of a casting furnace and the still untreated melt to be filled in at least into a casting of the casting furnace or in the form of a wire injection into the melt.

This optimizes the physical characteristics of the castings and significantly reduces the tendency to blow holes. This significantly reduces process times and process costs. The optimal determination of the treatment agents also leads to a very high yield of the Mg in the Fe.

For this purpose, it is advantageous that (2) after each furnace filling, a thermal analysis of the melt is carried out during the casting and the resulting process data serve to determine the forming agents that can be made available to the furnace furnace that follows immediately.

It is also advantageous that (3) the total weight of the melt is determined in a casting furnace (1) and / or in a transport pan and the melt is analyzed using a thermal measurement method. It is also advantageous that (4) during and / or after the casting process, the actual process data are continuously compared with target data or with target data stored in a computer, and the forming means are then determined.

For this purpose, it is advantageous that (5) the process data are determined at least the physical, mechanical and chemical parameters and / or the parameters such as strength index and shrinkage index are determined with the aid of the determination of individual cooling temperature curves of the melt (3).

For this purpose, it is also advantageous that (6) the physical, mechanical and chemical parameters such as strength index and void index are determined with the aid of the determination of individual cooling temperature curves of the melt.

It is advantageous that the thermal analysis takes place in one or more separate and closed crucibles of the measuring station, and in the case of several crucibles, each crucible has a different response means, e.g. May contain vaccines.

It is also advantageous that (8) the melt to be poured into a mold and the addition of the new melt to the casting furnace are carried out continuously during the determination of the process data. This can reduce the overall work process.

It is also advantageous for this that (9) the determined process data from the analysis of the melt, supported by the computer, continuously compared with the target data, adapted and can be used to determine the forming agents to be added subsequently.

It is of particular importance for the present invention that (10) for the formation of the separating layer between the melt in the casting or pressure casting furnace and the still untreated melt to be filled in, at least in one pouring of the pressure casting furnace, the inoculant involved in the process and finally the process-neutral separation material are entered first becomes.

This makes it possible to produce a directly castable GJV or GJS melt in a casting furnace. The process can be carried out very quickly because the previously necessary process steps can be dispensed with. The advantageous selection and the way in which the alloy components are introduced into the melt ensures a high level of process reliability when the physical characteristics and blowholes behavior of the cast parts is achieved. Furthermore, a controlled reaction leads to a reduced consumption of alloy components. The treatment agent produces very small amounts of slag, so that the slag only has to be carried out periodically at longer intervals. The high repeatability of the desired actual process data enables you, as already mentioned, to produce a directly castable GJV or GJS melt in a casting process in a one-step process.

For this purpose, it is advantageous that (11) the forming agents form a multilayer sandwich such as a triple sandwich or a quadruple sandwich, which as the bottom separating layer contains at least one FeSi-based inoculant, then at least one treatment agent such as metal and Mg and then as the top layer - contains at least one covering agent which does not influence the process of the melt. As a result, a premature reaction of the forming agent with the melt is avoided, the process time is reduced and, among other things, a uniform process of forming the melt in the casting furnace is achieved.

It is also advantageous that (12) the top layer is the covering agent, which consists of crushed steel such as steel granules or steel gravel.

According to a further development of the invention, an additional possibility is that (13) the treatment agent is an alloy which contains about 10% to 50% Mg and at least one further alloy component such as Cu, Ni, Sn or a lanthanoid such as cerium and into the melt is entered. Due to the advantageous composition of Mg in the treatment agent and the additional metal, a high output is achieved and there is only a low consumption of the treatment agent.

It is also advantageous that (14) the alloy contains 15% to 30% Mg and moreover at least Cu or another metal. By introducing the separating material, for example in the area of the cast-in of the pressure casting furnace, a separating layer is formed for the iron level and the iron to be filled in and therefore premature reaction and burning is prevented, so that, among other things, the desired process parameters are reliably achieved and a high level of process reliability combined with high output Mg is guaranteed up to 95%. It is also advantageous for this that (15) the treatment agent is an alloy which contains approximately 20% Mg and 80% Cu and is introduced into the melt.

According to a preferred embodiment of the solution according to the invention, it is finally provided that (16) the alloy is largely introduced into the pressure-casting furnace with the exclusion of oxygen from the atmosphere, the treatment and control of the germ state and / or the modification of the alloy components taking place within the pressure-casting furnace.

It is of particular importance for the present invention that (17) steel granules or steel gravel is provided as the top layer or as covering means, which forms a separating layer when the melt is poured in. the multi-layer sandwich being pressed into the crucible when the base iron is being poured in and the iron being formed only in this. The lower separating layer and the upper layer prevent a reaction in the pouring, the use of steel granules or steel gravel being provided as the top layer or as a covering agent.

In connection with the design and arrangement according to the invention, it is advantageous that (18) the treatment agent formed at least from metal and Mg is applied in a grain size to the inoculant or separating layer. As already mentioned, this produces very small amounts of slag. Furthermore, the treatment of the melt by the use of alloy components such as Cu and the inoculation of foreign germs results in a controllable reaction in the casting furnace due to the metallurgical separation. Cu is present as a pearlite generator in iron, its share in the treatment However, the amount of solution can advantageously be adjusted via the base content in the iron.

It is also advantageous that (19) the weight of the melt in the casting furnace and in the transport pan is determined before the formation agents such as inoculants, treatment agents, alloying agents, masking or separating material are input, i.e. The actual process data are determined, inter alia, by means of the thermal analysis and thus the amount of base iron to be filled in is determined and the melt is analyzed.

It is also advantageous that (20) the treating agent contains 0.03% to 0.09% Mg or 0.005% to 0.03% Mg with respect to the total melt.

When it comes to the production of the GJV material, that's tight

Process window 0.005% to 0.03% advantageous, with the material GJS the larger window 0.03% to 0.09%.

The method according to the invention and the advantageous introduction of the forming agent into the melt make it possible to automate the treatment, the introduction of foreign germs and the alloying, so that the automatically operating molding system is highly available by reducing the process time. The work process can be carried out very quickly, since the usual process steps can be dispensed with. Another advantage is the very high Mg output, which is between 80% and 95%.

Further advantages and details of the invention are explained in the claims and in the description and shown in the drawing. Show:

Fig. 1 shows the potting furnace with a multi-layer sandwich

Sprue, transport pan with base iron,

2 shows a process overview with a measuring and evaluation station for calculating the formation materials, an operating agent dosing system for providing the quantities and the addition into the pouring.

In Figure 1, a casting furnace with the essential functional parts is shown schematically, which can also be designed as a pressure casting furnace 1. The pressure casting furnace 1 has, among other things, a sprue 2, a spout 9 and a crucible 8, in which the iron melt, hereinafter referred to as melt 3, is kept at the required casting temperature with the aid of the inductor 10.

With the method according to the invention explained in more detail below, a process-reliable production of directly castable GJV-GGV and GJS-GGG melts is possible.

A more recent material development is a cast iron with Vermikulargraph.it, which is referred to below with the abbreviation GJV or GGV. With this material, the graphite is neither in the form of a lamella nor as a sphere, but rather as a knot or worm. The mechanical properties of this material lie between the cast iron with lamellar graphite and those of the cast iron with spheroidal graphite. However, its manufacture is difficult and requires a closely tolerated melt treatment. The cast iron with vermicular graphite shows compared to the conventional gray cast iron (GG) have a significantly higher tensile strength. Its properties allow higher pressures, for example, in cylinder blocks. At the same time, GGV-Guss offers the opportunity to reduce weight, so that castings can also be used in other areas for engine construction.

According to the method according to the invention (FIG. 1), the actual process data of the melt 3, 11 are first determined in the casting furnace during the casting, the calculation of the forming agent and then the filling of the individual materials as a multilayer sandwich 4.1 into the sprue 2, the lower one and the upper separating layer of the multilayer sandwich 4.1 between the melt 3 in the crucible 8 and the iron 11 to be filled in from the transport pan 12 prevents a premature reaction and a burning off of a treatment agent 5. The forming material 5 and the covering material 6 are identified in FIG. 1 as a separating layer. The base iron 11 is then filled in from the transport pan 12.

As can be seen from the drawing, the forming materials 4.1, as mentioned above, form the three-layer sandwich. Instead of the three-layer sandwich, a multi-layer sandwich can also be used, wherein the further layers can consist, for example, of further alloying agents which have a favorable effect on the melting process. The bottom layer of the formation materials 4.1 has a separating layer 4. This separating layer 4 also serves as an adjusting lever for adjusting the microbial content of the iron in the casting furnace 1. The separating layer 4 provides an inoculant and is advantageously made of an alloy based on FeSi or another material.

The treatment agent 5 can consist of an alloy which is approximately 10% to 50% Mg or 15% to 30% Mg or 10% to 25% Mg and moreover at least Cu or instead of Cu Ni, Sn or ?? and also contains other metal, the alloy being introduced or flushed into the melt 3 in a process section which will be explained later.

It is also advantageous if the treatment agent 5 which is introduced into the melt 3 is an alloy which contains approximately 20% Mg and 80% Cu or another metal in approximately the same amount.

It is also advantageous that the z. B. from metal-Mg, CuMg, NiMg or SnMg or the like treatment agent 5 in a predetermined grain size is applied to the separating layer 4. Before entering the forming agent 5, the furnace weight and the amount of base iron 11 to be fed are determined and one

Analysis of the melt 3 made.

The third layer is the covering means 6, which does not influence the process of the melt. B. steel gravel or steel granules can exist. These three layers form the multilayer sandwich 4.1 with the separating layer 4 and the covering means 6.

The untreated base iron 11 is with the help of the transport ladle or ladle 12 at the required speed in the forming agent 4,5 and Entry means 6 having poured in 2 and strikes the multilayer sandwich 4.1, so that it is rinsed or pressed into the crucible 8 as a sandwich in the absence of oxygen from the atmosphere and only reacts there.

The multilayer sandwich 4.1 thus forms the barrier between the iron level 8.1 and the iron to be poured in by means of the transport pan 12, the separating layers prevent a premature reaction of the treatment agent 5 and ultimately bring about a very good yield of the Mg up to 95%. Thus, as already mentioned, a directly pourable GGV or GGG melt in the casting furnace 1 is made possible by a one-step process.

The addition of quantities is calculated in the following process steps:

After the intended forming materials and the covering material 4.1 have been introduced into the sprue 2, the base iron 11 presses or rinses the multilayer sandwich 4.1 into the crucible 8, so that the iron is treated in the interior of the furnace with the aid of the Mg. The chemical final analysis can now be set using the special FeSi-based inoculant, the microbial count and possible alloying agents.

According to FIG. 2, the required actual process data of the melt 3 are recorded in the casting furnace 1 during the casting process. The comparison calculation with the target data is used to automatically determine the addition quantities of forming materials 4.1. The required process data include at least the determination of the strength index and the blow hole index, which can be done with the help of the individual cooling temperature curves of the melt 3 can be determined.

From at least one silo or also from two or three or more small silos 14, 15, 16 of a dosing system 13, the formation materials 4, 5 and covering materials 6 determined by a computer 17, as described above, are provided and in the required amount in the Dispensed 2, in which, as already mentioned, the multilayer sandwich 4.1 is formed.

In the silo 14 there is e.g. B. the vaccine such. B. one based on FeSi, in the second silo 15 the treatment agent 5 (Mg + metal) and in the third silo 16 the covering agent 6. The iron can also be formed with the aid of a wire injection.

The method according to the invention for an adaptable process control for the production of cast iron, in particular GJV and GJS and for calculating the addition quantities or treatment agents in the iron melt can also be carried out when using wire injection in the casting furnace.

The melt 3 is poured off continuously via the spout 9 during the measuring process. With the help of measuring devices 17, the thermal analysis in two closed crucibles, the weight of the melt, the casting temperature, the various other parameters are recorded and a chemical analysis of the melt 3 is carried out.

The strength index and shrinkage index for GJV can be determined using the thermal analysis described below: The structure is of crucial importance for the mechanical properties of cast components. This cast structure is determined during crystallization depending on the chemical composition, the cooling rate and the microbial count.

The parameter is the degree of saturation or the carbon equivalent. These determine the position of the cast iron alloy in the Fe-C diagram. These parameters are influenced by third emeate. Other important variables are the elements that directly influence the basic structure, namely the pearlite formers.

The cooling rate is influenced by a number of factors, namely: a) the ratio of volume to surface of the casting, b) the thermophysical properties of the core and molding materials,

c) the heat transfer from the cast body to the shape and the heat content of the melt.

The determination of the strength and shrinkage index for GJV using thermal analysis is explained below:

The difference between the specific volumes of solid and liquid is the cause of the occurrence of volume errors. The size of the volume deficit primarily depends on the respective casting material. With eutectic solidification, the expansion of the precipitated graphite counteracts the shrinkage of the austenite. This means that depending on the chemical composition, the cooling conditions and the microbial count "Self-feeding" is improved. For the "self-feeding" to be effective, endogenous shell-forming solidification must be present. The type of solidification is influenced by the chemical composition, the microbial count and the cooling rate.

Thermal analysis is a method for checking the quality of the melt. It is based on the recording of the time-temperature curve during the solidification of the melt and the evaluation of distinctive points that arise during the crystallization. If the liquidus temperature is undershot, nucleation and austenite dendrite growth begin in the melt. Dendrite growth releases heat. A kink occurs in the curve. When cooling further, the temperature drops below the eutectic equilibrium temperature. Below this temperature, growth-capable nuclei form on foreign substrates in the melt. During the subsequent grain growth, heat is released, which can show a rise in the temperature of the melt (recalescence).

The cooling curve thus always shows the interaction between heat removal and development and thus the course of crystallization.

The following parameters are determined by the thermal analysis:

a) carbon content, Sc, CE value,

b) tendency towards stable or metastable solidification,

c) assessment of the structure of GJS,

d) GJL microbial budgets estimate. Determination of the result data for the strength index.

The mechanical parameters are determined from the prescribed areas of the castings.

The result data for the void index are determined as follows:

The size of the

Defined area determined.

Parameters with a high correlation of the process data to the result data are determined via the mathematical model of the evaluation of the cooling curve of the melt in the crucibles 14, 15, 16 of the measuring station 17. The mathematical combination of these parts results in the strength and blowholes index.

The determination of the strength index and the shrinkage index for GJV by means of the thermal analysis takes place according to the following process sequence (Fig. 1 and 2):

1. pouring the melt 3 into a mold 19 and thereby removing the melt 3 from the spout 9 and pouring it into one or more small crucibles 14 to 16 of the measuring station 17,

2. Perform the thermal analysis using the

Measuring device 17,

3. Transfer of the determined data to the database of the

Process control computer measuring station 17,

3. evaluation of the actual process data,

4. Calculation of the strength and shrinkage index, comparison with the target process data, calculation of the addition quantities of alloy and formation material 4.1

5. Provision of the formation material 4.1 by means of

Dosing system 13

6. Transport of the transport pan 12 to the casting furnace 1, 7. Filling the forming agent 4.1 or the three or four layers in the pouring 2,

8. Filling the base iron 11 from the transport pan 12 into the pouring 2 of the casting furnace 1

Flushing the forming agent 4.1 into the melt 3 according to

Fig. 2,

9. continue as point 1 and following.

The determination of the strength index and the shrinkage index for GJV or GGV, GGG melts by means of the thermal analysis takes place for each filling with base iron 11 in the same way as described, so that a very precise determination of the amount or an adaptation of the forming agent 4.1 for subsequent ones Batches or melts are possible taking into account the target data.

As mentioned above, each crucible 14 to 16 of the measuring station 17 can have a different response means or vaccination means.

As already mentioned, the determined values or process data are forwarded to the database or the process control computer 17 and evaluated and are available for the determination or quantity of the formation means 4.1.

Later, the process data is continuously compared with the specified target data, so that the process can be continuously adapted or optimized (learning system).

As already mentioned, the two determined temperature cooling curves of the melt 3 in the crucibles 14 to 16 of the measuring station 17 become the strength index and the Cavity index determined. For this purpose, the process data are determined using a mathematically optimal model and compared with the result data.

On the basis of the parameters determined, automatic calculation and weighing of the individual forming agents 4.1 or automatic determination of the alloy components contained in the multilayer sandwich 4.1 is now possible. Then the forming agents are automatically added at least as a triple sandwich 4.1 into the sprue 2. This takes into account the contents of the furnace or transport kettle, so that an optimal formation of the melt 3 in the casting furnace 1 is possible.

Reference list

1 casting furnace, pressure casting furnace

2 sprue

3 melt

4 separating layer, FeSi (vaccine)

4.1 Buffer zone, buffer material, treatment agent

(corresponds to triple sandwich too

Formatting material)

5 treatment agent, alloy or inoculant

6 covering means

8 crucibles

8.1 Iron level

9 spout

10 inductor heating

11 base iron, untreated melt

12 transport ladle, ladle

13 dosing system

14 silo

15 silo

16 silo

17 computers

18 measuring device

19 form

Claims

1. Procedure for adaptable control of

Alloy composition of cast iron in casting furnaces, in particular of GJV and GJS, by calculating the addition amounts and adding forming agents and base iron, into the melt (3) of the casting furnace (1), comprising the steps

1.1 Determination of the amount of melt (3) in the casting furnace (1) and the amount of base iron (11) to be fed

1.2 Calculation of the expected physical and mechanical parameters, strength index and

Void index of the melt (3) with the help of a thermal and chemical analysis,

1.3 calculating the forming agents required for the desired physical and mechanical parameters to be introduced into the melt (3),

1.4 Entering the forming agent into the pouring furnace (2) of the casting furnace (1)

1.5 Pouring the base iron through the sprue (2) characterized in that the forming agent

- Treatment agent made of Mg or an alloy containing 10% to 50% Mg and at least one other

Alloy component such as Cu, Ni, Sn or a lanthanoid how cerium contains

- FeSi-based vaccines

- alloying agents,

- carburizing agents and

- Covered material made from crushed steel

and that

that the forming agent forms a multi-layer sandwich (4.1) which contains at least the inoculant (4) as the bottom layer, at least the treatment agent (5) above and at least the covering material (6) as the top layer.

2. The method according to claim 1,

characterized,

that after each casting of the casting furnace, the process data determined for the respective melt

Determination of the formation agent (4.1) for the

placed immediately afterwards in the potting furnace

Melt can be made available.

3. The method according to claim 1,

characterized,

that the process on a melt in one

Transport pan (12) can be used.

4. The method according to claim 1,

characterized,

that during and / or after pouring the

Actual process data are compared with target data or with target data stored in a computer and continuously adapted and then the formation means (4.1) are determined.

5. The method according to claim 1,

characterized, that the determination of the physical, mechanical and chemical and / or the determination of the characteristic values such as strength index and void index are carried out with the aid of the determination of individual cooling temperature curves of the melt (3).

6. The method according to claim 1,

characterized,

that during the determination of the process data

cast melt (3) in a mold (19) and the

The new melt (11) is continuously added to the casting furnace (1).

7. means for influencing the method according to claim 1, characterized in

that the covering means (6) is selected from crushed steel such as steel granulate or steel gravel.

8. Means for influencing the method according to claim 1, characterized in that

that a Mg-Cu alloy with 15% to 30% Mg is selected as the treatment agent (5).

9. The method according to claim 1,

characterized,

that the treatment agent (5) is an alloy which contains approximately 20% Mg and 80% Cu and is introduced into the melt (3).

10. The method according to claim 1,

characterized,

that the treatment agent (5) largely below

Exclusion of oxygen in the atmosphere

Pressure casting furnace (1) is entered, the Treatment and the control of the germ state and / or the modification of the alloy components take place within the pressure casting furnace (1).

11. The method according to claim 1,

characterized,

that a steel granulate or

Steel gravel is provided, which when pouring the

Melt (11) forms a separating layer.

12. The method according to claim 1,

characterized,

that the treatment agent (5) is applied in granular form to the vaccine (4).

13. Means for influencing the method according to claim 1, characterized in that

that the total melt after adding the

Treatment agent (5) contains 0.03% to 0.09% Mg or 0.005% to 0.03% Mg.