DE69813174T2 - Method and device for controlling the thickness of a liquid metallic layer on a filament - Google Patents

Description

The invention is directed to a Device for stripping / drying determined by means of a gas jet to control the thickness of a coating from a liquid metal, formed on a metallic filament, which from a bath of this liquid metal emerges and moves approximately vertically upwards out of this bath, this device is intended to be at a certain distance to be located above this bath and to include an element which is a tubular Has cylindrical recess through which the filament in can move substantially axially, with an injector in the tubular Recess is provided to a gas stream, for. B. nitrogen, towards the filament in the form of a sheet perpendicular to the Axis of said filament and radially aligned with respect to direct to the latter, so as to wipe off the excess on liquid Allow metal to be carried away from the bathroom by the filament becomes.

Several devices of the aforementioned type have been developed with varying degrees of success.

The basic principle is that liquid metal with the help of a gas lance (see US-A-3 778 862), which are generally formed by nitrogen becomes. The known devices have the disadvantage that they are Pressure profile of nitrogen, which is not uniformly round is formed around the filament. Therefore one calls when the thread reached a certain speed, irregularities in the filament forming coating out. On the other hand, you have to for each Diameter of the filament in particular in the known devices to limit and control the consumption of gas Provide element with different tubular recesses. This requires the replacement of one element with another each time matching element, which is common disassembly of the elements of the device and consequently valuable Time that is not negligible during production is, as is difficult regulation of coordination with the Filament when a new element with a cylindrical diameter is used in operation.

An essential goal of the present Invention is the disadvantages of the known devices to decrease, especially a quick change of the elements without the Need for realignment and above an increase in the speed of the throughput of the filaments combinatorial with a reduction in the thickness of the coating allow yourself to as much as possible to approach the minimum set by the standards, e.g. B. in the case of the wires (threads) ACSR is the ASTMB498 standard and to maintain a coating of very good quality and just as even as possible and with minimal gas consumption.

For this reason, according to the invention the above element in the device in a replaceable Mounted in the way that allows an element by another element according to the function of the diameter of the filament to be treated.

The aforementioned element according to the present Invention includes at least two blocks, preferably prismatic, in relation to each other are relocatable, on the one hand to a closed or working position, where the blocks are laid out one against the other by between them the said cylindrical tubular recess limit in which the filament can move essentially axially, and on the other hand in a protruding or open position, which the allows lateral access to the recess, especially around the filament to position in the device.

The invention relates in the same Way a stripping / drying process in particular to control the Thickness of a coating from liquid Metal, formed on a metallic filament, which from a bath this metallic liquid emerges and moves vertically above this bath, producing one Gas ring in the form of a right angle to the axis of the said filament lying sheet and radially aligned to the latter to the Wiping off the excess on liquid Allow metal to be carried away by the filament from the above Bath.

This method is characterized in that the thickness of this coating is regulated by changing it by means of a certain element having a recess and a circular transverse area through which said filament moves axially, the pressure of the stripping gas (P _nd ) at the outlet of the circular injector in function of the diameter (d) of the filament to be coated according to the formula as defined in claim 15.

The result is a procedure which allows, as a function of the diameter of the filament Speed of passage of the latter and the thickness of the coating the pressure of the gas at the inlet of the wiping agent used determine.

Other details and specifics the invention result from the following description of a not restrictive Example of two special embodiments of the stripping device according to the invention and a special embodiment of the method for Control of the thickness of the coating, which is on the one to be wrapped Filament is formed with reference to the attached drawings.

1 Figure 3 is a schematic cross-section through a filament coated with a liquid metal film which is subjected to drying or stripping by a sheet of gas according to the process of the invention.

2 is a perspective view of a first embodiment of the device according to the invention in its open position.

3 is an exploded perspective view of this first form of realization.

4 is a schematic view of the essential part of a second embodiment of the device according to the invention.

5 is an exploded perspective view of two essential fragments of this particular part of the second form of realization.

In the different figures the same reference numbers refer to identical or analogous elements.

As schematically in 1 shown, the present invention relates to an apparatus and a stripping method for controlling the thickness of a coating of liquid metal 1 , such as zinc, on a filament 2 , such as a steel wire with a round cross-section that comes from a bath 3 emerges from this liquid metal, following a substantially vertical direction.

Stripping the excess liquid metal through the wire 2 from the bathroom 3 is carried away by means of a sheet of gas under pressure, such as nitrogen, which is applied radially and at right angles to the surface of the wire 2 is directed like this by the arrows 4 in 1 is shown.

The device according to the invention is intended above this bath 3 to be assembled and includes one element 5 , preferably consisting of two parallelepipeds of identical blocks 5a and 5b which, when positioned against each other, have a cylindrical opening 6 limit that have a circular, vertical area in their axis through which the wire 2 for covering by means of the covering 1 can move essentially axially.

The gas sheet is cited by a circular injector 7 coaxial to the cylindrical space 6 educated. This injector is through an annular gap 7 parallel to a perpendicular plane to the axis of the tubular space 6 formed and has constant dimensions around the latter.

How detailed in the 2 and 3 shown, in a first embodiment of the device according to the invention the element 5 removably mounted on the stripping device in order to replace an element with a predetermined inside diameter by another element as a function of the diameter of the thread to be treated 2 to enable and this without having to disassemble the whole of the stripping device or to perform a realignment. Likewise, the two pre-cited different prismatic blocks can advantageously 5a and 5b be put one with respect to the other on the one hand in a closed position or working position and on the other hand in an open or distant position.

The blocks are in the closed position 5a and 5b firmly one against the other and delimit the tubular passage between them 6 with a circular open area in its two outer edges through which the wire extends 2 can move axially and in the lateral surface 9 the gap 7 is left out, which determines the coaxial, circular, pre-cited injector.

In the open position, which in 2 is shown, the two blocks 5a and 5b brought up to a certain distance from one another in a way that allows lateral access to the tubular recess 6 to have, for example, around a wire 2 in the stripping position.

In a preferred embodiment of the invention, both blocks have 5a and 5b each a semi-cylindrical cavity 6a and 6b on, these cavities forming the above-mentioned tubular cavity in the closed position. The block 5a is in a removable manner on a firm support 8a the scraper. The other block 5b is in relation to the block 5a on a mobile support 8b mounted and can translate movement in relation to the fixed support 8b between a closed position and the open position as indicated by the arrows in 2 is shown.

In the two special embodiments shown in the 2 to 4 , relies in this regard to postpone the mobile support 8b on two arms 10 from, which are each mounted on the latter.

An eccentric mechanism 11 with lever 15 works with the poor 10 at the side of the mobile support 8b together, being opposite to the firm support 8a is directed. That mechanism 11 includes a cylinder 12 that is around an axis 12a parallel to an axis 12b of the cylinder 12 can be rotated transversely with respect to the arms 10 extends.

On both sides of the cylinder 12 are coincident with the axis 12a shaft stubs 23 provided that are rotatably mounted in a removable manner in corresponding designs 14 that are in the upper edges of the arms 10 are spared.

A lever 15 is on the outer surface of the cylinder 12 screwed on and extends at right angles to the axis 12a the stumps 23 in a way that allows this cylinder to rotate subject to this axis 12a around, between a blockage position where the block 5a against the block 5b through the cylinder 12 is pressed thanks to the eccentricity between the axis 12b and the latter and the axis 12a and a deblocking position at which the ache 12b itself on the opposite side of the axis 12a with respect to the two blocks 5a and 5b emotional.

Around the stumps 23 through the openings 13 or to release the corresponding recesses in order to bring the device into its open position, as in 2 shown, an area in the form of a segment is offset on each of these stubs.

In the first embodiment of the device according to the invention, as shown in the 2 and 3 each block is shown 5a and 5b formed from two clearly arranged parts, which have the shape of a right-angled parallelepiped. These parts 18 and 19 are attached to one another in a movable form and to their corresponding support 8a and 8b with screws 24 with the exception of the aforementioned annular gap 7 , between their parts 18 and 19 which is made by a recess, in the form of semicircles in the upper surfaces 20 Of the parts 18 every block 5a and 5b , is formed.

That gap 7 communicates with a gas supply chamber 17 in the same way in the form of a semicircle, recessed in the part 19 and spreading over the entire height of the latter. This chamber 17 is connected to a gas supply line, not shown, connected above the support 8a through a line 25 who support 8a interspersed, starting from its upper surface 26 and extending into the chamber 17 of the block 8a ,

The support 8b carries the same channel 25 whose function it is, however, to enable the pressure measurements to be made by means of a manometer, not shown, connected to this channel 25 where he is on the top surface 26 of support ends.

In addition, the channel 25 of firm support 8a at that of the support 8b in the closed position of the blocks 8a and 8b through two lines 27 connected one part to another in the tubular cavity 22 are formed, such as the gap 7 of the block 5b to supply with gas.

Finally, the stripping device, as shown in the figures, comprises a fastening part 29 that allows them to be screwed 30 on a Positionierein direction, not shown, mobile to mount between predetermined limits.

The second embodiment of the drying or stripping device according to the invention, as shown in 4 is different from the first embodiment in that the blocks 5a and 5b each an inner interchangeable lining 29 have the lateral inner wall 9 the cylindrical recess 6 forms and therefore has the shape of a half cylinder.

This feed 28 is made up of two parts 28a and 28b formed, one arranged in the extension of the other parallel to the axis of the recess 6 excluding the previously cited column 7 between them. In this embodiment, the blocks 5a and 5b formed by a single part and the feed chamber 17 is inside the block 5a and 5b with respect to the gap 7 positioned. Likewise, in this second embodiment, the blocks 5a and 5b if necessary, firmly and not on the supports 8a and 8b be movable, since the sets are sufficient 28 to be replaced by sets with a different inner diameter as a function of the diameter of the wire 2 , which is to be provided with a metallic coating.

On the contrary, in the second embodiment, the blocks are sufficient 5a and 5b to replace yourself, which is in any case a much easier operation overall and much faster than changing the feed 28 ,

On the other hand, a cylindrical damping chamber extends 16 coaxial to the tubular recess 6 and extends below the latter and extends below to the bathroom 3 with communication with the surrounding atmosphere like that to the wire 2 a zone of slight positive pressure from the gas coming out of the injector 7 comes out to create. This chamber 16 has a diameter clearly above that of the annular recess 6 on to return to the bathroom 3 the excess of liquid metals, carried away by the wire 2 and stripped by the gas sheet.

In the same way, the invention relates to a drying or stripping method by means of a gas sheet, which allows the thickness of the coating of liquid metal 1 , made on a wire 2 to control the one from a bath 3 emerges with this liquid metal and moves vertically upwards over this bath.

in welcher bedeutet:
– Cpf = Dicke des Überzuges des Filamentes (2) nach Abstreifung gemessen in Metern,

bei der E die Dicke der Legierung repräsen tiert, ggf. auf dem Film gebildet, berechnet in Metern,
- U = die Geschwindigkeit des Filamentes (2) in m/sec.,
- H = R + kk, bei der

und hkk = die unmittelbare Dicke der Schicht des flüssigen Metalles auf dem Draht vor der Abstreifung entsprechend der Formel:

in der
u1 = die Viskosität in Pa.sec des mitgerissenen flüssigen Metalles bei der in Betracht gezogenen Temperatur;
p1 = die Volumenmasse des Metalls in kg/m³, welches bei der in Betracht gezogenen Temperatur mitgerissen wurde;
g = die Beschleunigung in m/sec² dank der Schwerkraft;
Kf = Koeffizient entsprechend des Zustandes des Drahtes und experimentell ermittelt;
– P = berechneter Koeffizient auf der Basis folgender Formel:

in der P_na der Druck im Ausgang des rohrförmigen Injektors ist, S die Dicke des Gasblattes an dessen Ausgang und Z entspricht der folgenden Formel:

bei der D der Durchmesser der rohrförmigen Ausnehmung(6) ist,
C = Abscherkoeffizient entsprechend der Formel:

This thickness depends on a number of parameters. According to the invention, a relationship between these different parameters is set, which makes it possible to use a device for drying / stripping to regulate the pressure (P _na ) of the stripping gas at the outlet of the gap as a function of the diameter (d) of the wire to be coated, which moves at a predetermined vertical speed (U) with respect to the stripping gas sheet. This relation is as follows:

in which means:
- Cpf = thickness of the filament coating ( 2 ) measured in meters after stripping,

where E represents the thickness of the alloy, possibly formed on the film, calculated in meters,
- U = the speed of the filament ( 2 ) in m / sec.,
- H = R + kk where

and hkk = the immediate thickness of the layer of liquid metal on the wire before stripping according to the formula:

in the
u1 = the viscosity in Pa.sec of the entrained liquid metal at the temperature under consideration;
p1 = the volume mass of the metal in kg / m ³ which was entrained at the temperature under consideration;
g = acceleration in m / sec ² thanks to gravity;
Kf = coefficient according to the condition of the wire and determined experimentally;
- P = calculated coefficient based on the following formula:

where P _{na is} the pressure at the outlet of the tubular injector, S is the thickness of the gas sheet at its outlet and Z corresponds to the following formula:

where D is the diameter of the tubular recess ( 6 ) is
C = shear coefficient according to the formula:

The thickness of the coating can be calculated in g / m ² using the formula Cpf × 103 × p1.

If the wire is in a liquid metal is bathed, which is suitable to tighten a cover, the diameter of the wire to be considered itself enlarged twice the thickness of the coating. This is the case, for example, if the wire is made of iron and if the plating metal is formed by zinc. In such a case, an Fe-Zn coating is formed the wire rising from the bathroom.

In order to allow the determination of the pressure on the pre-cited manometer at the entrance of the device used, which must be applied to the desired pressure P _na at the outlet of the injector 7 to get In order to form the desired thickness of metallic coating on the wire, repeated tests must be carried out on this device in such a way that the loss of charge between the pressure gauge and the outlet of the injector can be predetermined.

Once the relation between the charge loss and the pressure measured on the pressure gauge could be adjusted, the gas pressure can be determined on the pressure gauge to obtain the pressure P _na and the value of the coefficient P can be used using formula (b) given above Calculate in the ratio (a) to obtain the desired thickness Cpf of the metallic coating on the wire to be treated.

The quoted ratio (a) is preferred for the wire diameters, which may include an alloy coating between 0.8 and 8 mm can vary applied.

It has been found that, according to the invention, if you reduce the consumption of gas to a strict minimum, the ratio between the diameter of the wire must 2 and that of the tubular recess 6 or the distance between the gap 7 are kept below certain limits according to practice, proceed as follows: Diameter of the wire Diameter of the tubular cavity used 0.8 to 1.8 mm 6 mm 1.8 to 2 mm 8 mm 2.8 to 3.5 mm 10 mm 3.5 to 8 mm 12 mm

This therefore implies that it is important without having to realign the device the diameter of the tubular Determine cavity, easily and quickly the parts of the latter replaced.

Below is an application example of the quoted relationship (a) for given a stripping / drying device, intended for one Steel wire with a predetermined diameter (d), which is in a predetermined speed (U) and a zinc coating with a thickness of 350 to 400 g / m should be applied.

More specifically, the known or calculated parameters that have to be taken into account in order to obtain a ratio (a) are as follows:
U: 1.083m / s
S: 0.0006m
d: 0.00179 (with the coating of the Zn-Fe alloy)
D: 0.006m
p1: 7140kg / m ³
u1: 0.0034165Pa.s
pa: 1.1132615kg / m ³
inter alia: 0.0000165Pa.s
g: 9.81m / s ²
C. -90.6459 H: 0.001052

hkk: 568.10 g / m ²
hk: 0.0000796m.

The device used is of the type shown in the 2 and 3 is shown.

If one introduces the parameters cited above and inserts a desired thickness Cpf in the ratio (a), one can calculate the coefficient (P) which, when inserted into the formula (b), allows the pressure P _na to be obtained and consequently the pressure of the gas to be set on the manometer at the entrance to the device.

In addition, another possibility, generally more practical, is to try by introducing some value for P _na into the formula (b) that allows one to obtain a corresponding value Cpf in the ratio (a) and the To decrease or increase the value P _na as a function of the value Cpf obtained until a value Cpf is obtained between the fixed limit values for the thickness of the metallic coating of the wire, which in this case is between 350 and 400 g / m.

In this way, if P _{na is given} a value of 55 mm H ₂ O, the value Cpf 0.0000531 m is thus 379.40 g / m2.

It is important to note that the ratio (a), which was given above cannot only be applied to Scraper devices according to the invention, but also for all types of devices for stripping or drying, who insert a gas sheet that is oriented horizontally against a wire, that moves vertically from below out of a bath of liquid metal.

The invention is of course not limited on embodiments the stripping device as shown in the accompanying drawings is and on a stripping process, as described above, but in the same way variants envisaged without departing from the present invention, in particular in terms of the means used, access to the annular cavity, through which the to be covered Wire moves.

Although the invention can be applied can for the coating any kind of thread or elongated substrate, no matter which Metal or what metal alloy, it will be advantageous used to make steel wires with a coating made of zinc or zinc alloy.

Claims (16)

Device for stripping / drying by means of a gas jet intended to control the thickness of a coating ( 1 ) made of a liquid metal, formed on a metallic filament ( 2 ), which from a bathroom ( 3 ) this liquid metal emerges and moves approximately vertically above this bath, this device being intended to be at a certain distance above this bath ( 10 ) to be arranged and an element ( 5 ) which has a tubular cylindrical recess through which the filament ( 2 ) can move essentially axially therethrough, an injector ( 7 ) in the tubular recess ( 6 ) is provided to a gas stream, e.g. B. nitrogen, in the direction of the filament, this element for drying the excess liquid metal, which is from the filament ( 2 ) from the above bath ( 3 ) is carried along, is arranged, characterized in that the injector ( 7 ) is annular and coaxial with respect to the filament and on the inside of the tubular cylindrical recess ( 6 ), which is open on its two outer sides, in the direction of said filament the gas jet in the form of a sheet, perpendicular to the axis of the filament and oriented radially with respect to the latter; and that the above element ( 5 ) is mounted in an adjustable manner to allow the replacement of an element with a predetermined inner diameter by another element depending on the diameter of the filament to be treated; and in that the aforementioned element has at least two blocks ( 5a ) and ( 5b ) comprises, preferably prism-shaped, which are displaceable with respect to one another, on the one hand in a closed or working position in which the blocks ( 5a and 5b ) one against the other, by defining between them the cylindrical tubular recess in which the filament ( 2 ) can move essentially axially, and on the other hand into a protruding or open position, which allows lateral access to the recess ( 6 ) allowed, especially to position the filament in the device. Device according to claim 1, characterized in that said tubular, cylindrical recess ( 6 ) a side wall ( 9 ) in which a column ( 7 ), which determines the coaxial annular injector mentioned above. Device according to one of claims 1 and 2, characterized in that the aforementioned element ( 2 ) different blocks ( 5a ) and (5b), each of these blocks having a recess in a semi-cylindrical shape ( 6a ) and ( 6b ), the two recesses in the above-mentioned closed position the aforementioned tubular recess ( 6 ) form. Device according to one of claims 1 to 3, characterized in that one of the two blocks ( 5a ) of the aforementioned element ( 5 ) removable on a fixed support ( 8a ) is mounted, the other block ( 5b ) with respect to the block mentioned ( 5a ) primarily on mobile support ( 8b ) is mounted, which can experience a shift between a closed form in which the blocks ( 5a ) and ( 5b ) against the other, and in an open position in which they are at a certain distance from one another in a manner in which one can approach the aforementioned tubular recess ( 6 ) can reach. Device according to claim 4, characterized in that the aforementioned movable support ( 8b ) on two arms ( 10a ) and (10b) arranged on the solid support ( 8a ) and mounted on both sides of the latter. Device according to claim 5, characterized in that the movable support ( 8b ) slidable on the aforementioned two arms ( 10a ) and ( 10b ) is resting, an eccentric mechanism ( 11 ) on these arms ( 10a ) and ( 10b ) is mounted on the side next to the movable support ( 8b ) opposite him towards the solid support ( 8a ) directed, this mechanism ( 11 ) a cylinder ( 12 ) which can be rotated about an eccentric axis and which extends transversely with respect to the arms ( 10 ) extends in a way around the movable support ( 8b ) in its closed position using the cylinder ( 12 ) by pressing the axis of the latter towards the solid support ( 8a ) approaches and around the mobile carrier ( 8b ) to release by the cylinder ( 12 ) is rotated around said eccentric axis by removing the cylindrical axis from the carrier ( 8a ). Device according to one of claims 1 to 6, characterized in that a damping chamber ( 16 ) to enclose the filament ( 2 ) below the ring-shaped injector ( 7 ) and the aforementioned element ( 5 ) is intended to drain above the bath ( 3 ) with liquid metal and in connection with the surrounding atmosphere in a way to around the filament ( 2 ) between that bathroom ( 3 ) and the device to create a zone of slight overpressure by the gas coming from the injector. Device according to one of claims 1 to 7, characterized in that the aforementioned annular column ( 7 ) with a feed chamber ( 17 ) communicates, recessed in the aforementioned blocks, the latter may be connected to a supply of gas under pressure, which allows a gas flow to be produced in the form of a sheet. Device according to one of claims 1 to 8, characterized in that the aforementioned element ( 5 ) has an inner interchangeable lining, which has a side wall with the aforementioned tubular recess ( 6 ) forms and the aforementioned injector ( 7 ) having. Device according to one of claims 2 to 9, characterized in that each of the blocks ( 5a ) and ( 5b ) two areas ( 18 ) and (19), clearly lying one above the other and firmly connected to one another, which cut out the aforementioned annular recess between them. Apparatus according to claim 10, characterized in that the feed chamber ( 17 ) in the upper part ( 19 ) the blocks ( 5a ) and ( 5b ) is arranged above the annular gap ( 7 ) in connection with the latter, essentially over its entire scope. Device according to one of claims 10 or 11, characterized in that the annular gap in the upper surface ( 20 ) of the lower parts ( 18 ) the blocks ( 5a ) and ( 5b ) is left out. Device according to one of claims 11 or 12, characterized in that the feed chamber ( 17 ) inside the supports ( 8a ) and ( 8b ) up to an inlet of compressed gas, whereby connecting means ( 21 ) in the supports ( 8a ) and ( 8b ) are provided which allow the feed chamber ( 17 ) the blocks ( 5a ) and ( 5b ) connect one to the other once the blocks are in their closed position. Device according to one of claims 4 to 13, characterized in that the blocks ( 5a ) and ( 5b ) below the supports ( 8a ) and ( 8b ) are suspended, the semi-cylindrical grooves ( 6a ) and ( 6b ), recessed in these blocks, extend in the supports ( 8a ) and ( 8b ) over the entire amount of the latter for limitation in the same way by the supports ( 8a ) and ( 8b ), in the closed position of the blocks ( 5a ) and ( 5b ), a tubular recess, coaxial to the through the blocks ( 5a ) and ( 5b ) limited tubular recess ( 6 ). Method of stripping / drying by means of a gas jet, determined to control the thickness of a Cover ( 1 ) made of a liquid metal, formed on a metallic filament ( 2 ), which from a bathroom ( 3 ) this metallic liquid escapes and is located vertically above this bath ( 3 ) moves around the filament, under production, starting from an annular injector ( 2 ) around, a gas ring in the form of a sheet lying at right angles to the axis of the said filament and radially aligned with the latter in order to allow the excess liquid metal to be wiped off, entrained by the filament ( 2 ) from the above bath ( 3 ), in particular using a device according to one of Claims 1 to 14, characterized in that the thickness (Cpf) of this coating ( 1 ) by changing a certain element ( 5 ) regulates that a tubular recess ( 6 ) and has a circular transverse area through which the said filament extends axially ( 2 ) moves, the pressure of the drying gas (P _n d) at the outlet of the circular injector ( 7 ) in function of the diameter (d) of the filament to be covered ( 2 ) according to the following formula:

in which means: - Cpf = thickness of the filament coating ( 2 ) measured in meters after drying,

where E represents the thickness of the alloy, possibly calculated on the formed in meters, - U = the speed of the filament in m / sec., - H = R + kk, both

and hkk = the immediate thickness of the layer of liquid metal on the wire before stripping / drying according to the formula:

in which u1 = the viscosity in Pa.sec of the entrained liquid metal at the temperature under consideration; p1 = the volume mass of the metal in kg / m ³ which was entrained at the temperature under consideration; g = acceleration in m / sec ² thanks to gravity; Kf = coefficient according to the condition of the wire and determined experimentally; - P = calculated coefficient based on the following formula:

where P _{na is} the pressure at the outlet of the tubular injector, S is the thickness of the gas sheet at its outlet and Z corresponds to the following formula:

where D is the diameter of the tubular recess ( 6 ), C = shear coefficient according to the formula:

A method according to claim 15, characterized in that a bath ( 3 ) with zinc or zinc compounds in liquid form and filaments made of steel ( 2 ) for coating with a layer of zinc or a zinc compound ( 1 ).