Field of the invention
[0001] The present invention relates to a method and a device for controlling the thickness
of a coating on a flat metal product, such as a steel strip, during the continuous
galvanizing process of the strip by hot immersion, also referred to briefly "hot dip"
by the English term.
Prior Art
[0002] In the galvanizing process by immersion in a hot bath a metal strip, suitably thermally
pre-treated in a non-oxidising /reducing atmosphere, is dipped in a bath of melted
Zn (440°C-470°C) and is guided out in a vertical direction by rollers immersed in
the bath.
[0003] The amount of liquid Zn extracted by the strip during the passage through the melted
bath is determined by the balance between the force of gravity and the viscous forces,
and the thickness of the layer of liquid Zn which is deposited on both surfaces of
the strip, results as proportional to the speed of the strip and the physical properties
of the melted Zn, such as kinematic viscosity and surface tension.
[0004] In order to reduce the thickness of the Zn layer deposited on the strip to those
values required by final application specifications of the strips, jets or blades
of air, known in English as "Air Knives", or of some other gas, usually steam or N2,
are commonly used.
[0005] The devices employed generally comprise two nozzles having a rectangular section
or a section having some other form, positioned at the sides of the strip at a predetermined
distance from both the strip and the free surface of the Zn bath, from which a gas
jet exits advantageously at room temperature. These gas jets act to reduce the thickness
of the zinc layer that covers the surface of the strip, forcing part of the liquid
metal to return towards the bath.
[0006] Since the final thickness of the coating is proportional to the speed of the strip,
in order to obtain the same thickness at increasing speed, the pressure exercised
by the air knives must be increased. This effect is obtained by an increase in the
gas flow rate or the reduction of the opening of the air knife nozzles.
[0007] There exists, however, a speed limit for the strip feeding over which the surface
of the coating layer is subject to instability and wave formation to the point of
releasing liquid and solid drops or particles in the environment in proximity of the
air knives. This phenomenon, referred to as "splashing", is generally amplified by
the vibrations and oscillations that always occur on the strip. "Splashing" provokes
large problems both for product quality and for environmental safety because of the
dust released, and this represents one of the main causes that limits the strip speed
and therefore the productivity-in actual galvanizing plants.
[0008] Another problem is due to the different fluid-dynamic and thermal situation present
on the centre of the strip with respect to the strip edges. In fact, this situation
leads to the fact that the thickness is not uniform but is greater at the edges. In
fact, the edges of the strip cool more rapidly than the centre of the strip creating
variations in the physical properties of the liquid Zn, in particular in the kinematic
viscosity, that generate surface forces (Marangoni effect) provoking an accumulation
of coating near the edges. The problem is resolved only partially using knives or
masks to deflect the gas jet at the edges of the strip, or using butterfly nozzles
that increase the gas flow rate on the edges.
[0009] The accumulation of the coating near the edges, in addition to create problems with
winding, and successively problems of flatness of the galvanized strip, causes- also
problems of uniformity in the coating properties when the strip is subjected to successive
treatments, for example a heating and a holding for an appropriate time at a temperature
close to the melting point of the zinc, a treatment referred to as "galvannealing"
in English. Furthermore, this accumulation does not permit to reduce to a minimum
the amount of Zn necessary to obtain a given coating, with the consequential economical
disadvantages.
[0010] A limit of air-knife technology is represented also by the fact that the airflow
produces a coating oxidation that increases in intensity in proportion to the increase
in speed and gas flow rate. This generates defects in the final product and contributes
towards releasing dust into the environment. The realization of cutting systems using
inert gas, such as N2, used to prevent this drawback, are only able to resolve the
problem partially and in any case at a higher cost when compared to common air knife
systems.
[0011] Another limit of this technology is that of provoking a strong cooling and therefore
the premature solidification of the Zn under the action of the air knife, especially
when the supply pressure is increased with the purpose of obtaining increasingly thinner
coatings. This signifies diminishing the efficacy of Zn thickness reduction.
[0012] A further limit regards the pressure of the air, or gas, which must be maintained
within certain limits in order to prevent reaching supersonic air speeds with the
consequential problems of vibration, beating and instability in the strip position,
and excessive noise levels in the plant.
[0013] As a consequence of this, in the case where the final thickness of the coating is
fixed at a relatively reduced value, since it is not possible to increase the air
pressure too much, the strip speed must be reduced, and therefore also the production
line productivity, and this is in contrast with current needs in sales competitiveness,
which require speeds over 200 metres/min.
[0014] In order to solve at least some of the problems described above, various solutions
have been proposed that use magnetic fields to reduce the thickness of the coating.
[0015] If implemented alone, these magnetic solutions, albeit solving in many cases some
of the problem described above, are unable, however, to increase the current maximum
productivity of galvanizing lines, since the volume force produced by said devices
on the layer of zinc, which has an intensity such as not to cause problems of overheating
of the zinc and of the strip, is at the most equal to the one generated by current
pneumatic systems used on galvanizing lines.
[0016] As an alternative, solutions have been proposed that provide the combined use of
magnetic fields and air knives. Also these combined solutions, however, present disadvantages.
[0017] An example of these combined solutions is described in the document
JP61227158, in which there are provided the direct injection of currents on the moving strip,
in the direction of its width, and the action of an induced magnetic field acting
in a direction perpendicular to the surface of the strip. Said solution is of difficult
practical application because it involves various problems of contact between the
moving part, i.e., the strip, and the stationary part, represented by the electrodes.
There is then the possibility of damage to the strip, which must be able to move at
high speed.
[0018] Furthermore, superposition of the jet of gas on the area of action of the magnetic
forces can be obtained only by inclining the jet of the gas towards said area of action
and, hence, reducing the force of pressure on the layer of zinc and increasing the
shear stress, with the consequent increase in the risk of inducing surface instability
and hence the undesirable phenomenon of "splashing".
EP 0525387 A1 discloses a method for controlling coating weight on a hot-dipping steel strip, with
the provision of flowing a high-frequency current strong enough to magnetically saturate
the steel strip through a pair of high-frequency current conducting paths to induce
a high-frequency current of an opposite phase in the steel strip, so that a magnetic
pressure acting on surfaces of the steel strip is generated by interaction of the
induced high-frequency current with a high-frequency current of the high-frequency
current conducting paths.>
WO 2006/006911 A1,
WO 2007/004945 A1 and
BE 1011059A6 disclose the combined use magnetic fields and gas fets on the same area of a hot
difs coated elongated metallic element to control the thickness of the metallic element.
FR 2754545 A discloses a pair of electromagnetic induction coils for controlling coating on hot-diffed
metal strip. A screen for confining the electromagnetic field is associated with each
induction coil.
[0019] There is hence felt the need to provide a method and a related device for controlling
the thickness of a coating of metal products, at output from a hot bath, which is
able is to overcome the aforesaid drawbacks.
Summary of the invention
[0020] A purpose of the present invention is to provide a method and a related device for
carrying out an operation of controlled removal of the coating in excess in the final
stage of continuous galvanization by hot dipping of a flat metal product, such as
for example a steel strip, by means of jointed use of electromagnetic fields and jets
of gas in such a way as to increase the maximum productivity of current galvanization
lines.
[0021] Another purpose of the invention regards the possibility of effective control of
the weight of the coating and the uniformity of distribution thereof.
[0022] A further purpose of the present invention is to reduce and possibly eliminate the
problem of "splashing".
[0023] A final purpose of the present invention is to control and reduce to a minimum the
oscillations of the strip induced by the operation of removal of the coating in excess.
[0024] In order to achieve the purposes mentioned, according to a first aspect of the present
invention, a method is provided for controlling the thickness of coating of a flat
metal product, according to claim 1.
[0025] A second aspect of the invention provides a device for controlling the thickness
of coating of a flat metal product, suitable for defining a feeding direction when-it
exits from a bath of coating material in continuous hot-dip galvanization processes
in accordance with claim 7.
[0026] In the device of the invention the inductors are suitable for producing three magnetic
field loops, among which two loops are generated by each inductor respectively and
a third loop is generated in common by the two inductors. The means for supplying
the nozzles, comprising a gas manifold, are at least partially made of magnetic material
with high electrical resistivity.
[0027] The method of the invention provides using a non-continuous magnetic field, either
alternating or pulsed, which impinges upon both of the layers of molten material of
the coating and upon the strip. In particular, the spatial components of the electromagnetic
force produced by the non-continuous magnetic field that are oriented downwards, i.e.
tangentially along the surface of the strip, together with the transverse ones, i.e.
directed orthogonal to said surface, are used advantageously for removing the coating
material in excess from the steel strip that moves upwards as it exits from the bath
of molten material. Furthermore, the transverse components of the electromagnetic
force are used for controlling oscillation of the strip and for keeping the latter
aligned at the centre of the working gap. Advantageously, oscillation or deformation
of the strip during feeding thereof is thus avoided.
[0028] In this way, the combination of the non-continuous magnetic field, generating the
electromagnetic forces, and of the jets of gas produces the force necessary for effective
removal of the coating in excess, together with control of the oscillations of the
strip in the area of removal for favouring uniformity of the coating thickness. Advantageously,
the more gradual distribution of said electromagnetic forces with respect to the pneumatic
ones reduces the problem of splashing up to the point where it is completely solved.
[0029] Furthermore, thanks to the non-continuous magnetic field, there is advantageously
generated an induction heating of the strip and of the coating material directly in
the area of action of the jets of gas, thus preventing intensive cooling of the coating
material by the gas and the risk of a premature solidification thereof. Induction
heating, in addition to increasing the surface temperature of the coating material,
advantageously reduces the surface tension and viscosity thereof. Thus, thanks to
induction heating and to the jointed action of the jets of gas and of the electromagnetic
forces, a coating is obtained of much smaller and more uniform thickness than in current
plants, as well as higher production rates. According to the present invention it
is possible to coat, for example, steel strips with zinc, zinc-iron alloys and zinc-aluminium
alloys, aluminium, and aluminium-tin alloys.
Brief description of the figures
[0030] Further characteristics and advantages will emerge more clearly from the detailed
description of preferred, but non-exclusive, embodiments of the method and of the
device of the invention, with the aid of the annexed drawings, in which:
Figure 1 illustrates a cross section of the entire device in accordance with the present
invention;
Figure 2 illustrates the distributions of the magnetic field in the area of operation
for two extreme values of the phase shift angle between the magnetic fluxes in the
left-hand and right-hand inductors (as viewed in Figure 1);
Figure 3 illustrates a cross section of a variant of the entire device in accordance
with the present invention;
Figure 4 illustrates the trend of electromagnetic forces that are generated for removing
the coating material in excess;
Figure 5 illustrates the trend of the thickness of the coating for different phase
shift angles in the windings of the left-hand and right-hand inductors and in the
case where activation of said inductors is not provided;
Figure 6 illustrates a distribution of the fields, of the induced currents, and of
the electromagnetic forces on the strip and on the layers of coating, suitable both
for removing the excess of coating material from the strip and for stabilizing the
strip in the gap between the inductors;
Figure 7 illustrates a graph regarding the means producing a change of direction of
the electromagnetic forces that hold the strip at the centre of the magnetic gap;
Figure 8 illustrates a graph with the trend of the maximum induction heating of the
coating material and of the strip in the active area;
Figure 9 illustrates a cross section of another variant of the invention with electromagnetic
shields inside and outside of the inductors;
Figure 10 illustrates the effect of the internal electromagnetic shield on the temperature
of the jets of gas;
Figure 11 illustrates a distribution of the positioning of the sensors for detecting
the position of the strip.
Detailed description of preferred embodiments of the invention
[0031] With reference to Figure 1, the device according to the present invention comprises
means for generating non-continuous electromagnetic fields for removal of the coating
material in excess by means of the electromagnetic forces induced on the coating layers,
said means being advantageously combined with means for generating jets of gas, for
example air, for removal of the coating material in excess also by means of fluid-dynamic
forces.
[0032] In particular, the means for generating electromagnetic fields comprise two inductors,
each constituted for example by two windings or coils 5 wound around a core 4, substantially
C-shaped, whilst the means for generating jets of gas comprise, for each inductor,
support and/or supply means for supporting and/or supplying nozzles 2, comprising
a gas supply manifold 1 and the nozzles themselves, placed in proximity of each surface
of major extension of the steel strip at output from the molten bath of the coating
material. The pressure of supply of the nozzles is preferably comprised between 0,1
bar and 1 bar.
[0033] The cores 4, substantially C-shaped, are of the laminated type, or compact, made
of ferromagnetic or magneto-dielectric or ferritic material, whilst the coils 5 are
arranged facing one another on each side of the steel strip 3 and- are- water-cooled.
There is advantageously provided the control of the frequency of the alternating magnetic
field according to the type and quality of the coating to be removed.
[0034] In accordance with the present invention, the ensemble of the device constituted
by the inductors together with the gas manifold 1 and the gas nozzles 2 can be inclined
according-to different angles and displaced in the direction of the strip by appropriate
movement means. The variation of the orientation of the inductors and the nozzles,
which can take place in a fixed way or else in an uncoupled way, enables to modify
the conditions of removal of the coating in excess. Advantageously, since the support
and/or supply means, which comprise the gas-supply manifold 1 and the nozzles 2, are
arranged within the ferromagnetic cores 4, the superposition of the gas jets on the
area of action of the magnetic forces is always guaranteed without this implying any
reduction of the force of pneumatic pressure on the layer of the zinc coating or any
increase in the shear stress that would cause the undesirable phenomenon of "splashing".
The nozzles 2, arranged in proximity of the magnetic yoke poles 14', 14" of each ferromagnetic
core 4, can be located inside or outside the inductors.
[0035] Advantageously, the combined effect of the induced electromagnetic forces and of
the fluid-dynamic forces of the gas jets enables an increase in the efficiency of
reduction of the coating thickness, as compared to gas knives alone, and enables a
more uniform and thinner layer of coating material 11 to be obtained. In fact, by
means of the inductors of the device of the invention it is possible to:
• prevent cooling and premature solidification of the coating layers 11 thanks to
the heating, by the Joule effect, of the strip 3 and of the coating layers 11 generated
by the induced parasitic currents;
• reduce the viscosity and the surface tension of the layer of coating, which is still
liquid, once again by the Joule effect, facilitating the task of removal of the material
in excess by the gas knives.
[0036] The gas knives, in turn, advantageously perform the function of control of the temperature,
preventing an excessive induction heating both of the coating layers 11 and of the
steel strip 3. In this way, then, the induced currents never overheat the coating
layers 11 and the steel strip 3, thus preventing any undesirable saturation and loss
of the ferromagnetic properties of the strip. Since the ferromagnetic properties are
preserved thanks to the cooling produced by the gas, the steel strip 3 concentrates
the magnetic flux on its own surface, more precisely on the interface between the
coating layer and the strip, and in this way, the electromagnetic forces are increased
several times making more efficient the effect of removal of the coating material
in excess.
[0037] In accordance with the present invention, it is advantageous to supply the coils
5 with a single-phase alternate current having a medium-frequency of a value comprised
in the range 100 and 500 Hz. With such a frequency range it is possible to maintain
the ferromagnetic properties of the steel strip unalterated, because said strip is
not overheated; it is possible to obtain an electromagnetic force sufficiently intense
to remove the coating material in excess and to keep the strip aligned in the central
position in the magnetic gap 13. Optimal results have been obtained, in particular,
with a frequency range of 100÷480 Hz.
[0038] In accordance with a variant, the invention provides the possibility of using just
the means for generating electromagnetic fields individually.
[0039] When the inductors are preferably used together with the gas knives, in order to
concentrate the electromagnetic power in the area of impact of the gas on the strip,
the distance between the magnetic yoke poles or polar expansions 14', 14", top and
bottom respectively, of the ferromagnetic cores 4, i.e. the distance between the common
branches of the magnetic flux, is as small as is allowed by the nozzles 2 that generate
the gas knife, which are arranged advantageously inside or outside the inductors in
proximity of said poles 14', 14". Said distance between the poles is preferably comprised
between 15 and 50 mm, in order to concentrate the electromagnetic force along a strip
stretch longitudinally extending for 5÷30 mm that coincides with the stretch on which
the pneumatic force acts. With respect to a device exploiting a "travelling electromagnetic
field", the device of the invention allows to obtain higher electromagnetic forces,
having a maximum intensity higher of about 20% with respect to that obtained by aforesaid
travelling field devices, and to better exploit the concentrated cooling action of
the air knives.
[0040] In accordance with another variant illustrated in Figure 3, the magnetic yoke itself
performs also the function of air knife. This is possible in so far as the polar expansions
or poles 14' and 14" are shaped appropriately in order to define the nozzles 2 adapted
to generate the gas jets. In said variant, partitions 30, or slots, are advantageously
provided at the inlet section of said nozzles 2, said slots having the purpose of
equalizing the flow rate within the nozzles themselves. The nozzles 2, in this case,
are therefore defined by the configuration of the polar expansion 14', 14" and have
a passage orefice, which, in cross section (Figure 3), has a tapered shape in the
feeding direction of the strip. In the embodiment of Figure 3, in particular, said
passage orefice comprises two successive tapered stretches defining mutually incident
directions. In this case, the distance between the magnetic yoke poles 14', 14", top
and bottom respectively, is comprised between 0,5 and 5 mm.
[0041] In this variant, the means for generating electromagnetic fields comprise two inductors,
each constituted, for example, by a winding or coil 5 wound around the core 4, as
illustrated in Figure 3, which is substantially C-shaped. The windings 5 are supplied
with alternate or pulsed alternate current. Inside each core 4 there are provided
the supply means for supplying the nozzles, comprising a manifold not illustrated.
[0042] Figure 2 shows, with reference to the variant of Figure 1, the lines of magnetic
flux 15 generated by the coils 5 in the ferromagnetic core 4 and outside the core
(dispersed flux).
[0043] Each inductor creates its own loop of magnetic flux 152, 153, which closes between
pairs of poles 14', 14" of the ferromagnetic core 4, as illustrated in the right-hand
part of Figure 2, and a common loop 151 of magnetic flux embracing both of the ferromagnetic
cores 4, as illustrated in the left-hand part of Figure 2. Thus, the magnetic flux
152, 153 of each inductor passes along both of the surfaces of the strip 3 in a substantially
vertical direction (right-hand part of Figure 2), i.e. tangentially to the surfaces,
and simultaneously the loop of common magnetic flux 151, which flows between the two
inductors, passes twice through the steel strip 3 in directions substantially perpendicular
to the surfaces 11 of the strip 3 and opposite each other according to the arrows
18', 18", visible in Figure 6, respectively in the area of the top magnetic poles
14' and in the area of the bottom magnetic poles 14".
[0044] Figure 6 shows that the component of the magnetic flux oriented in a direction perpendicular
to the strip 3 induces in the strip two loops of induced current 17', 17", which surround,
respectively, the magnetic flux indicated by the arrows 18', 18". These two current
loops 17' and 17" join in the impact area 12 of the jets of gas, for example air,
up to the point of possibly being superposed. Thanks to the interaction of these induced
currents 17', 17" with the magnetic flux 18', 18", longitudinal electromagnetic forces.
(Lorentz forces) are produced, oriented upwards 20' and downwards 20", respectively.
The electromagnetic forces oriented downwards 20" produce a shear effect and hence
a effect of removal of the coating material in excess, and they are advantageously
concentrated along a strip stretch longitudinally extending for 5÷30 mm, preferably
10÷25 mm, thanks to aforesaid configurations of the magnetic poles.
[0045] Since the electromagnetic forces 20" are generated by the interaction of the current
loop 17' with the magnetic flux 18", in order to maximize the intensity thereof the
shape of the two magnetic yoke poles 14', 14" is, in both of the variants, tapered
and optimized for increasing to a maximum the intensity of current in the loop 17'
and for concentrating the magnetic flux 18" on the strip 3 and on the coating layers
11. In this way, the undesirable electromagnetic forces directed upwards 20', produced
by the interaction of the current loop 17" with the magnetic fluxes 18' and 18", are
reduced considerably until they are almost eliminated.
[0046] At the same time, the electromagnetic forces directed downwards 20" have a distribution
such as to produce a more gradual reduction of the layer of zinc, with respect to
the reduction that would be produced by the pneumatic action only, so as to overcome
the problem of splashing.
[0047] The interaction of the current loops 17', 17" with the magnetic flux 19 of each ferromagnetic
core 4 (associated to the loops of magnetic flux 152, 153 visible in Figure 2) produces
the electromagnetic forces 21, which have an orientation perpendicular to the surfaces
of the strip, as illustrated in Figure 6.
[0048] If the overall thickness of the strip 3 and of the coating layers 11 is comparable
to the depth of penetration of the magnetic flux in the materials, the magnetic flux
19 of each inductor induces a current loop 22 that surrounds the strip 3 and the coating
layers 11. The interaction between the currents 22 and the electromagnetic flux 19
creates transverse electromagnetic forces 23', 23", which are substantially perpendicular
both to the strip 3 and to the coating layers 11.
[0049] The gradient of the electromagnetic forces 23', 23" also produces a shear effect
for removing the coating material in excess from the strip 3. From the difference
between the forces 23' and 23" there can be generated a resultant force perpendicular
to the strip 3.
[0050] Advantageously, the tapered shape of the two magnetic yoke poles 14', 14" is such
as to maximize also the electromagnetic forces that act in a direction perpendicular
to the strip 3.
[0051] When the inductors are used in combination with the air knives, it is possible to
obtain better results in terms of reduction of the coating layers 11 by means of superposition
of the electromagnetic forces 20" directed downwards and of the maximum gradient of
the electromagnetic forces 23', 23" with the area of impact 12 of the gas jets.
[0052] Represented in Figure 4 is a graph of the longitudinal electromagnetic forces 20',
20" and transverse electromagnetic forces 23', 23" that appear in the coating layers
11 as a result of application of an alternating or pulsed magnetic field when the
two inductors generate the common magnetic flux. Represented on the axis of the ordinates
is the density of these electromagnetic forces or Lorentz forces in N/m
3; represented, instead, on the axis of the abscissae is the spatial coordinate along
the vertical feeding direction of the strip.
[0053] The relation between the longitudinal magnetic flux 19 in each inductor and the common
transverse magnetic fluxes 18', 18" in the two inductors changes as a function of
the phase shift between the currents in the windings of each inductor. When the currents
in the windings of the two left-hand and right-hand inductors are in phase, i.e.,
the phase shift of the currents is Δϕ = 0 (as illustrated in Figure 2 on the left),
the magnetic fluxes 18', 18" join in a common loop 151 of magnetic flux, and the longitudinal
electromagnetic forces 20', 20" reach their maximum, as likewise does induction heating
of the strip.
[0054] When the currents in the windings of the left-hand and right-hand inductors are in
phase opposition, i.e., the phase shift of the currents is Δϕ = 180° (as illustrated
in Figure 2 on the right), the loop of magnetic flux 151 vanishes and there remains
only the longitudinal magnetic flux 19, generated by the loops 152, 153 of magnetic
flux. In this case, the induction heating of the strip is minimum.
[0055] By varying the phase shift angle in the range ±180°, longitudinal 19 and transverse
18', 18" magnetic fluxes having an intermediate intensity comprised between the minimum
and maximum values are generated.
[0056] Since the steel strip 3 is ferromagnetic, it is strongly attracted by the magnetic
yoke poles 14' and 14". Consequently, to counter said attraction, the electromagnetic
force or Lorentz force generated by the difference between the values of phase shift
of the currents as a function of the displacement of the strip 3 from the centre of
the magnetic gap 13 is advantageously exploited. As already mentioned above, when
the currents in the windings have a phase shift comprised in the range ±180°, in the
area of action of the electromagnetic forces there exist two magnetic fluxes 19 and
18', 18", and there also arise transverse integral forces 21 and the difference between
the transverse electromagnetic forces 23' and 23" that tends to move the strip 3 in
a horizontal direction.
[0057] The direction of the resultant of the forces varies as a function of the orientation
of the longitudinal magnetic flux 19, and the orientation of the total Lorentz force,
which results from the sum of the forces 21, 23' and 23", changes with the variation
of the phase shift between the currents in the windings arranged on one side and in
those arranged on the opposite side of the strip 3. By reversing the sign of the phase
angle of the current and keeping the same values of the modulus of the current, the
force changes sign. This phenomenon can be used for countering the ferromagnetic attraction
of the strip and for suppressing the oscillations of position of the strip 3.
[0058] For this reason, said total Lorentz force is defined as "force of repulsion".
[0059] The position of the strip in the magnetic gap 13 between the two inductors is measured
with sensors of an optical, or capacitive, or inductive type 14, as illustrated in
Figure 11, which are suitable for sending the signal necessary to the power source
of the inductors in order to change the sign of the phase angle and the amplitude
of the electrical parameters of the inductors when the strip 3 deviates from the position
centred in the gap 13.
[0060] The variation of electrical parameters of the supply system of the inductors, such
as the value and/or phase of the voltage and the amplitude and/or phase of the current,
can be used also for measuring the position of the strip and for generating the signal
necessary for the power source to change the phase shift.
[0061] Figure 5 shows the trend of the thickness of the coating as a function of the different
phase shift in the inductors on both sides of the strip. The curve 200 represents
the trend of the thickness of the coating in the case where there is not provided
removal of the coating material in excess also by means of the electromagnetic forces.
The curves 201 and 202 represent, respectively, the trend of the thickness of the
coating on the left-hand side and on the right-hand side of the strip in the case
where these electromagnetic forces of removal are provided.
[0062] The thickness of the coating is reduced from approximately 15 µm to approximately
5,5 µm when the action of removal of the coating in excess by the electromagnetic
field is added to the normal jet of gas, in the case where the variation of phase
between the currents in the inductors is equal to zero. It may be noted that the thickness
of the coating remains almost constant, with a value lower than 6 µm of thickness,
until the phase shift reaches a value of Δϕ = 100°.
[0063] In the graph of Figure 7 it may be noted that the force of repulsion 24 (Lorentz
force), which results from the sum of the forces 21, 23' and 23" in Figure 6 for countering
the ferromagnetic attraction exerted by the poles of the inductor, is maximum on the
strip 3 when the phase shift is approximately 90°.
[0064] In the same Figure 7, the curves 240 and 241 represent the trend as the phase shift
Δϕ, respectively, of the Maxwell force and of the sum of the Maxwell force and of
the force of repulsion 24 vary.
[0065] The graph of Figure 8 illustrates the dependence of the maximum temperatures that
can be generated on the steel strip 3 (curve 100) and on the two coating layers 11
(curve 101) by induction heating, without the use of gas knives, when the phase shift
between variations of currents in the inductors varies in the range ±180°. It is possible
to obtain a minimum local heating for Δϕ = ±30°.
[0066] In this way, the optimal phase shift between the supply currents in the inductors
of both sides of the strip can be determined in the range ϕΔ = ±90°. In this range
it is possible to obtain the necessary repulsive forces, without losing the possibility
of obtaining a small thickness of the coating.
[0067] In order to reduce the induction heating of the support and supply means for supporting
and supplying the gas knives, said means being arranged inside each ferromagnetic
core 4 and comprising the manifold 1 and possibly the nozzles 2, at least one-high-conductivity
electrical shield 16 can be provided, arranged between said means and the core 4 (as
illustrated in Figure 9), which fulfils two functions:
- preventing induction overheating of the air knife; and
- concentrating the magnetic flux directly in the area 12 where the gas jet acts. Figure
10 shows that, using the high-conductivity shield, with a phase shift of Δϕ = ±30°
the shield enables a reduction of the temperature of the gas knives to a regular level.
[0068] Supplementary high-conductivity electrical shields 160', 160" can be provided, arranged
outside each ferromagnetic core 4 and in proximity of the poles of the magnetic yokes
14', 14", in order to reduce the induction heating on the strip 3 and on the coating
layer 11, when the temperatures become excessive for the process. By means of this
appropriate positioning of the shields 160', 160', it is possible to limit the reduction
of the magnetic flux in the area 12 where the gas jet acts to maintain the effectiveness
of the system of removal of the coating material in excess.
[0069] When the inductors are used in combination with gas knives, in order to increase
the magnetic flux in the area 12 where the gas acts and to increase the electromagnetic
forces, it is possible to make all the support and supply means of the gas knives,
or alternatively only the nozzles 2, by using a magnetic material having a high electrical
resistance, e.g., iron or laminated steel, ferrite or magneto-dielectric material.
[0070] According to a further variant, the aforesaid electromagnetic shields, internal or
external to the magnetic cores 4, can be shaped in such a way as to constitute themselves
the nozzles for the gas jets. In this case, then, the nozzles 2 will be defined by
the configuration of the electromagnetic shields.
[0071] In a particular embodiment of the invention, a concentration of the horizontal electromagnetic
forces, acting in a direction substantially orthogonal to the strip, is obtained at
the edges of the strip for removing the material in excess on the edges.
[0072] In an advantageous variant of the invention, the process of removal of the coating
material in excess provides the use of the device getting only the inductors to work,
without setting in operation the air knives. It is moreover possible to get the device
to act only on one of the faces of the strip, leaving the coating unaltered on the
second face, or else it is possible to get the inductors and the air knives-to-work
in various combinations on one or both sides of the strip.
1. A method for controlling the thickness of coating of a flat metal product (3), the
product defining a feeding direction when it exits from a bath of molten coating material
in continuous hot-dip galvanization processes, wherein there are provided two inductors,
each adapted to be supplied with single-phase alternate or impulsive current, having
magnetic cores (4), substantially C-shaped and windings (5), wound on said cores,
arranged on each side of said flat metal product at its surfaces (11) of major extension,
suitable for producing electromagnetic forces induced on said flat metal product and
cooperating with nozzles (2) suitable for producing at least one jet of gas directed
on at least one of the surfaces (11) of said flat metal product, said method comprising
blowing jets of gas through the nozzles (2) on an area of impact (12) of the surfaces
(11) of the flat metal product (3) coated by the molten coating material after exit
from a dip in said bath, activating said inductors with said alternate or impulsive
current with frequency in a range comprised between 100 and 500 Hz thereby producing
said electromagnetic forces so that they act on said area of impact (12) to make more
efficient the action of removal of the material by said jets of gas and to control
the oscillations of the flat metal product (3), characterized in that first high conductivity shields (16) are arranged inside each ferromagnetic core
(4) to protect the gas jets from overheating and to concentrate the magnetic flux
directly in said area of impact (12), and in that second high conductivity shields (160', 160") are provide outside each ferromagnetic
core to reduce the induction heating on the flat metal product (3).
2. The method according to claim 1, wherein the alternate or impulsive supply currents
have a controlled phase shift angle, suitable for creating three magnetic- field loops,
of which the first (152) and the second (153) loops are generated by each inductor
separately, and the third loop (151) is generated in common by the two inductors,
3. The method according to claim 2, wherein the phase shift angle of the supply currents
is comprised in the range ±180 °, preferably equal to ±90°.
4. The method according to claim 3, wherein among the electromagnetic forces those acting
in a direction substantially orthogonal to the flat metal product can be reversed
in direction in a controlled way to keep said metal product in a centered position
by means of a reversal of the phase angle between the supply currents of the two inductors.
5. The method according to claim 4, wherein there are provided detection of the position
of the flat metal product by means of sensors (14) in a magnetic gap (13) between
the two inductors and emission of a signal for possibly varying electrical parameters
of supply of the two inductors.
6. A device for controlling the thickness of coating of a flat metal product (3), the
product being suitable for defining a feeding direction when it exits from a bath
of coating material in continuous hot-dip galvanization processes, comprising:
- two inductors, which can be supplied with single-phase non-continuous current, arranged
respectively at the surfaces (11) of major extension of the flat metal product, each
inductor having a substantially C-shaped magnetic core (4) and at least one winding
(5), wound around said core, suitable for producing electromagnetic forces acting
on at least one surface (11) of the flat metal product;
- nozzles (2), cooperating respectively with said inductors, suitable for producing
at least one jet of gas acting on at least one surface (11) of the flat metal product,
said nozzles being arranged in proximity of magnetic yoke poles (14', 14") of each
magnetic core (4);
- supply means, provided within each inductor, for supplying said nozzles (2); so
that the action of said at least one jet of gas and of said electromagnetic forces
is concentrated on one and the same area of impact (12) of the surface (11) of the
flat metal product (3) in order to make more efficient the action of removal of the
coating material in excess and to control oscillation of the strip itself,
said device being
characterized in that
there are provided first high-conductivity concentrators of magnetic flux (16), for
concentrating the flux in the area of impact (12), arranged between said supply means
and the core (4), and second high-conductivity concentrators of magnetic flux (160',
160"), for concentrating the flux in the area of impact (12), arranged outside each
magnetic core (4) and in proximity of said poles (14', 14").
7. The device according to claim 6, wherein the nozzles (2) are defined by the configuration
of magnetic yoke poles (14', 14") of each magnetic core (4) and there are provided
partitions (30) at an inlet section of said nozzles (2) for equalizing the flow rate
of gas within the nozzles themselves.
8. The device according to claim 6, wherein the nozzles (2) are arranged inside or outside
the inductors.
9. The device according to claim 7 or 8 wherein the poles of the magnetic yokes (14',14")
are tapered, and their shape is optimized for maximizing the electromagnetic force
on the coating directed downwards and/or in a direction perpendicular to the flat
metal product (3)
1. Verfahren zum Steuern der Dicke der Beschichtung eines flachen Metallprodukts (3),
wobei das Produkt eine Zufuhrrichtung definiert, wenn es aus einem Bad von geschmolzenem
Beschichtungsmaterial in kontinuierlichen Feuerverzinkungsprozessen austritt, wobei
zwei Induktionsspulen bereitgestellt sind, wobei jede dafür ausgelegt ist, dass ihr
ein Einphasenwechselstrom oder -impulsstrom zugeführt wird, wobei sie Magnetkerne
(4), die im Wesentlichen C-förmig sind, und Wicklungen (5), die auf die genannten
Kerne gewickelt sind, die auf jeder Seite desgenanntenflachen Metallprodukts auf seinen
Oberflächen (11) in der Hauptausdehnung angeordnet sind, die für die Erzeugung elektromagnetischer
Kräfte geeignet sind, die in demgenannten flachen Metallprodukt induziert werden,
und die mit Düsen (2) zusammenwirken, die dafür geeignet sind, wenigstens einen Gasstrahl
zu erzeugen, der auf wenigstens eine der Oberflächen (11) desgenannten flachen Metallprodukts
gerichtet ist,aufweisen, wobei dasgenannte Verfahren umfasst: Blasen von Gasstrahlen
durch die Düsen (2) in einen Auftreffbereich (12)der Oberflächen (11) des flachen
Metallprodukts (3), das durch das geschmolzene Beschichtungsmaterial beschichtet wird,
nach Austritt von einem Tauchen in dasgenannte Bad, Aktivieren dergenannten Induktionsspulen
mit demgenannten Wechselstrom oderImpulsstrom mit einer Frequenz in einem Bereich
zwischen 100 und 500 Hz und dadurch Erzeugen dergenannten elektromagnetischen Kräfte
in der Weise, dass sie auf dengenannten Auftreffbereich (12) wirken, um die Wirkung
des Entfernens des Materials durch diegenannten Gasstrahlen effizienter zu machen
und um die Oszillationen des flachen Metallprodukts (3) zu steuern, dadurch gekennzeichnet, dass innerhalb jedes ferromagnetischen Kerns (4) erste Abschirmungen (16) mit hoher Leitfähigkeit
angeordnet sind, um die Gasstrahlen vor Überhitzung zu schützen und um den magnetischen
Fluss direkt in demgenannten Auftreffbereich (12) zu konzentrieren, und dadurch, dass
außerhalb jedes ferromagnetischen Kerns zweite Abschirmungen (160', 160") mit hoher
Leitfähigkeit bereitgestellt sind, um die Induktionserwärmung an dem flachen Metallprodukt
(3) zu verringern.
2. Verfahren gemäß Anspruch 1, bei dem die Wechselspeiseströme oder Impulsspeiseströme
einen gesteuerten Phasenverschiebungswinkel aufweisen, der geeignet ist, drei Magnetfeldschleifen
zu erzeugen, von denen die erste (152) und die zweite (153) Schleife durch jede Induktionsspule
getrennt erzeugt werden und die dritte Schleife (151) durch die zwei Induktionsspulen
gemeinsam erzeugt wird.
3. Verfahren gemäß Anspruch 2, bei dem der Phasenverschiebungswinkel der Speiseströme
im Bereich von ±180° liegt und vorzugsweise gleich ±90° ist.
4. Verfahren gemäß Anspruch 3, bei dem unter den elektromagnetischen Kräften jene, die
in einer Richtung im Wesentlichen orthogonal zu dem flachen Metallprodukt wirken,
in Bezug auf die Richtung auf gesteuerte Weise umgekehrt werden können, um das Metallprodukt
mittels einer Umkehrung des Phasenwinkels zwischen den Speiseströmen der zwei Induktionsspulen
in einer zentrierten Position zu halten.
5. Verfahren gemäß Anspruch 4, bei dem die Detektion der Position des flachen Metallprodukts
mittels Sensoren (14) in einem Magnetspalt (13) zwischen den zwei Emissionsspulen
und die Emission eines Signals zum möglichen Ändern elektrischer Parameter der Speisung
der zwei Induktionsspulen bereitgestellt werden.
6. Vorrichtung zum Steuern der Dicke der Beschichtung eines flachen Metallprodukts (3),
wobei das Produkt dazu geeignet ist, eine Zufuhrrichtung zu definieren, wenn es aus
einen Bad von Beschichtungsmaterial in kontinuierlichen Feuerverzinkungsprozessen
austritt, wobei die Vorrichtung umfasst:
- zwei Induktionsspulen, denen ein diskontinuierlicher Einphasenstrom zugeführt werden
kann, die jeweils bei den Oberflächen (11) der Hauptausdehnung des flachen Metallprodukts
angeordnet sind, wobei jede Induktionsspule einen im Wesentlichen C-förmigen Magnetkern
(4) und wenigstens eine Wicklung (5), die um dengenannten Kern gewickelt ist, die
dafür geeignet ist, elektromagnetische Kräfte zu erzeugen, die auf wenigstens eine
Oberfläche (11) des flachen Metallprodukts wirken, aufweist;
- Düsen (2), die jeweils mit dengenannten Induktionsspulen zusammenwirken, die geeignet
sind, wenigstens einen Gasstrahl zu erzeugen, der auf wenigstens eine Oberfläche (11)
des flachen Metallprodukts wirkt, wobei diegenannten Düsen in der Nähe von Magnetjochpolen
(14', 14") jedes Magnetkerns (4) angeordnet sind;
- Speisemittel, die innerhalb jeder Induktionsspule bereitgestellt sind, um die genanntenDüsen
(2) zu speisen,sodass die Wirkung desgenannten wenigstens einen Gasstrahls und dergenannten
elektromagnetischen Kräfte auf ein und denselben Auftreffbereich (12) der Oberfläche
(11) des flachen Metallprodukts (3) konzentriert wird, um die Wirkung des Entfernensdes
überschüssigen Beschichtungsmaterials effizienter zu machen und um die Oszillation
des Streifens selbst zu steuern,
wobei diegenannte Vorrichtung
dadurch gekennzeichnet, dass
erste Konzentratoren für denmagnetischen Fluss (16) mit hoher Leitfähigkeit, um den
Fluss in dem Auftreffbereich (12) zu konzentrieren, die zwischen den genanntenSpeisemitteln
und dem Kern (4) angeordnet sind, und zweite Konzentratoren für den magnetischen Fluss
(160', 160") mit hoher Leitfähigkeit, um den Fluss in dem Auftreffbereich (12) zu
konzentrieren, die außerhalb jedes Magnetkerns (4) und in der Nähe dergenannten Pole
(14', 14") angeordnet sind, bereitgestellt sind.
7. Vorrichtung gemäß Anspruch 6, bei der die Düsen (2) durch die Konfiguration von Magnetjochpolen
(14', 14") jedes Magnetkerns (4) definiert sind und bei der bei einem Einlassabschnitt
dergenannten Düsen (2) Trennwände (30) bereitgestellt sind, um die Durchflussmenge
des Gases innerhalb der Düsen selbst anzugleichen.
8. Vorrichtung gemäß Anspruch 6, bei der die Düsen (2) innerhalb oder außerhalb der Induktionsspulen
angeordnet sind.
9. Vorrichtung gemäß Anspruch 7 oder 8, bei der die Pole der Magnetjoche (14', 14") verjüngt
sind und ihre Form so optimiert ist, dass die nach unten und/oder in eine Richtung
senkrecht zu dem flachen Metallprodukt (3) gerichtete elektromagnetische Kraft auf
die Beschichtung maximiert ist.
1. Procédé pour contrôler l'épaisseur du revêtement d'un produit métallique plat (3),
le produit définissant une direction d'amenée lorsqu'il sort d'un bain de matériau
de revêtement fondu dans des processus de galvanisation à chaud, où sont prévues deux
inductances, chacune apte à être alimentée avec un courant monophasé alternatif ou
impulsif, ayant des noyaux magnétiques (4) sensiblement en forme de C, et des enroulements
(5), enroulés sur lesdits noyaux, agencés de chaque côté dudit produit métallique
plat à ses surfaces (11) d'une extension majeure, aptes à produire des forces électromagnétiques
induites sur ledit produit métallique plat et coopérant avec des buses (2) aptes à
produire au moins un jet de gaz dirigé sur au moins une des surfaces (11) dudit produit
métallique plat, ledit procédé comprenant le soufflage de jets de gaz à travers les
buses (2) sur une zone d'impact (12) des surfaces (11) du produit métallique plat
(3) revêtu par le matériau de revêtement fondu après la sortie d'une immersion dans
ledit bain, activer lesdites inductances avec ledit courant alternatif ou impulsionnel
avec une fréquence dans une plage comprise entre 100 et 500Hz, en produisant ainsi
lesdites forces électromagnétiques de sorte qu'elles agissent sur ladite zone d'impact
(12) pour rendre plus efficace l'action du retrait du matériau par lesdits jets de
gaz et pour contrôler les oscillations du produit métallique plat (3), caractérisé en ce que des premières protections de haute conductivité (16) sont agencées à l'intérieur
de chaque noyau ferromagnétique (4) pour protéger les jets de gaz contre une surchauffe
et pour concentrer le flux magnétique directement dans ladite zone d'impact (12),
et en ce que des deuxièmes protections de conductivité élevée (160', 160") sont réalisées à l'extérieur
de chaque noyau ferromagnétique pour réduire le chauffage par induction sur le produit
métallique plat (3).
2. Procédé selon la revendication 1, où les courants d'alimentation alternatifs ou impulsionnels
ont un angle de décalage de phase commandé, apte à créer trois boucles de champ magnétique,
la première (152) et la deuxième (153) boucle étant produite par chaque inductance
séparément, et la troisième boucle (151) est produite en commun par les deux inductances.
3. Procédé selon la revendication 2, dans lequel l'angle de décalage de phase des courants
d'alimentation est compris dans la plage ± 180°, et il est de préférence égal à ±
90°.
4. Procédé selon la revendication 3, dans lequel parmi les forces électromagnétiques,
celles agissant dans une direction sensiblement orthogonale au produit métallique
plat peuvent être inversées en direction d'une manière contrôlée pour maintenir ledit
produit métallique dans une position centrée au moyen d'une inversion de l'angle de
phase entre les courants d'alimentation des deux inductances.
5. Procédé selon la revendication 4, dans lequel sont prévues la détection de la position
du produit métallique plat par des capteurs (14) dans un entrefer magnétique (13)
entre les deux inductances et l'émission d'un signal pour éventuellement varier les
paramètres électriques de l'alimentation des deux inductances.
6. Dispositif de contrôle de l'épaisseur du revêtement d'un produit métallique plat (3),
le produit étant apte pour la définition d'une direction d'amenée lorsqu'il sort d'un
bain de matériau de revêtement dans des processus de galvanisation continus à chauds,
comprenant:
- deux inductances, qui peuvent être alimentées en courant monophasé non continu,
agencées respectivement aux surfaces (11) de l'extension majeure du produit métallique
plat, chaque inductance ayant un noyau magnétique sensiblement en forme de C (4) et
au moins un enroulement (5), enroulé autour dudit noyau, apte à produire des forces
électromagnétiques agissant sur au moins une surface (11) du produit métallique plat;
- des buses (2), coopérant respectivement avec lesdites inductances, aptes à produire
au moins un jet de gaz agissant sur au moins une surface (11) du produit métallique
plat, lesdites buses étant agencées à proximité de pôles de carcasse d'aimant (14',
14") de chaque noyau magnétique (4);
- des moyens d'alimentation, réalisés dans chaque inductance, pour l'alimentation
desdites buses (2);
de sorte que l'action dudit au moins un jet de gaz et desdites forces électromagnétiques
est concentrée sur une même zone d'impact (12) de la surface (11) du produit métallique
plat (3) pour rendre plus efficace l'action de retrait du matériau de revêtement excédentaire
et pour contrôler l'oscillation de la bande elle-même,
ledit dispositif étant caractérisé en ce que sont prévus des premiers concentrateurs de haute conductivité du flux magnétique
(16), pour concentrer le flux dans la zone d'impact (12), agencés entre lesdits moyens
d'alimentation et le noyau (4), et des deuxièmes concentrateurs de conductivité élevée
du flux magnétique (160', 160") pour concentrer le flux dans la zone d'impact (12),
agencés à l'extérieur de chaque noyau magnétique (4) et à proximité desdits pôles
(14', 14").
7. Dispositif selon la revendication 6, où les buses (2) sont définies par la configuration
des pôles de carcasse d'aimant (14', 14") de chaque noyau magnétique (4), et des séparations
(30) sont prévues à une section d'admission desdites buses (2) pour égaliser le débit
d'écoulement du gaz dans les buses elles-mêmes.
8. Dispositif selon la revendication 6, où les buses (2) sont agencées à l'intérieur
ou à l'extérieur des inductances.
9. Dispositif selon la revendication 7 ou 8, où les pôles des carcasses d'aimant (14',
14") sont effilés, et leur forme est optimisée pour amener au maximum la force électromagnétique
sur le revêtement dirigée vers le bas et/ou dans une direction perpendiculaire au
produit métallique plat (3).