Apparatus for cooling a strip prior to a minispangle operation

Abstract

A steel strip (10) is conveyed through a galvanizing bath (20) of molten zinc, a zinc coating weight control device (12), and a minispangle box assembly (16). The steel strip emerges from the zinc coating weight control device (12) with a non-uniform temperature distribution across its width in which it is warmer in the center and cooler at its edges. A differential, pre-cooler assembly (18) cools the steel strip selectively and non-uniformly across its width in a manner which is complimentary to the temperature distribution thereacross. In this manner, the steel strip exits the pre-cooler assembly (18) and enters the minispangle box assembly (16) with a more uniform temperature distribution. This results in a more uniform minispangle appearance on the strip (10) as it exits the minispangle box assembly (16). The pre-cooler assembly includes a plurality of nozzle pairs (32a, 32b; 34a, 34b; 36a, 36b; 38a, 38b). The nozzles of each nozzle pair are disposed in a facing relationship on opposite sides of a work path, and include a pair of conduits (60a, 60b) which define an array of apertures (62a, 62b) therealong. A damper (66a, 66b) is provided to selectively cover the apertures in each array. Each damper has a leading edge (72a, 72b) which is somewhat U-shaped so that as the damper is adjusted relative to the associated conduit, the apertures of the array are progressively covered from the outer edges toward the center, or progressively uncovered from the center toward the edges.

Description

BACKGROUND OF THE INVENTION

The present application relates to the art of metal processing. The invention finds particular application in conjunction with cooling strip steel after immersion in a galvanizing bath and in preparation for minimizing the spangle size of the steel coating. This invention will be described with particular reference thereto. It is to be appreciated, however, that the invention is also applicable to other strip handling systems in which selective cooling across the strip width is advantageous.

Conventionally in preparation for minispangling, hot strip steel is dipped into a bath of molten zinc. The excess zinc is wiped off the steel by a coating weight control device, and then the steel and coating are allowed to cool naturally in air or are uniformly cooled by forced air coolers. In many cases the strip steel and coating are not a uniform temperature across the width of the strip. This non-uniform temperature is a result of many factors such as variations in steel strip and coating thicknesses, the natural tendency of the strip edges to cool faster than the center of the strip, non-uniform cooling by the coating weight control device and non-uniformities in thermal treatments of the strip prior to the galvanizing bath. When the steel strip and coating temperature are not uniform across the strip prior to entry into the minispangle box, the minispangle coating appearance will be non-uniform. In this case, one area of strip may have minimized spangles and another area will have partially reduced or full size spangles (irregular shaped crystals) as seen on regular galvanized steel strip.

The present invention contemplates a new and improved differential pre-cooling apparatus which selectively provides non-uniform cooling across the strip width to compensate for inherent uneven steel strip and coating temperatures.

SUMMARY OF THE INVENTION

In accordance with a first aspect of the invention, a new minispangling apparatus is provided. A conveying means conveys a continuous strip of hot steel through a galvanizing bath of molten zinc and a coating weight control device. A minispangle box is conventionally disposed downstream from the coating weight control device. The coating weight control device and the natural cooling area upstream of the minispangle box have a tendency to cool the strip steel unevenly across its width, most commonly cooling the strip more rapidly adjacent its edges. In cases where additional cooling of the steel strip and coating are required, a pre-cooler assembly is disposed between the coating weight control device and the minispangle box. The present invention includes nozzle means for causing air to flow against the strip across its transverse width. A nozzle restricting means restricts air flow through the nozzle means selectively and non-uniformly across the strip width. In this manner, the amount of air flow against the strip is selectively varied across the width such that the non-uniform cooling compliments the non-uniform temperature. This brings the strip to a generally uniform temperature across its width prior to entry in the minispangle box.

A first advantage of the present invention is the production of a minispangled surface appearance which is substantially uniform across the strip width.

Another advantage of the invention is that it selectively provides differential cooling across a strip width.

Another advantage of the invention is the selective adjustment of the temperature of a strip across its width for rendering the strip temperature substantially uniform.

Another advantage of the invention is fewer minispangle box adjustments, eg., height location, recirculation flow rate and zinc feed rate, are required to adjust to changing operating conditions such as line speeds, strip dimensions, coating weight thicknesses, and galvanizing bath temperatures.

Still further advantages of the present invention will become apparent to others upon a reading and understanding of the following detailed description of the preferred embodiment.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention may take form in certain parts and arrangements of parts, a preferred embodiment of which will be described in detail in this specification and illustrated in the accompanying drawings which form a part hereof and wherein:

FIG. 1 is a front elevational view of a minispangling apparatus which includes the present invention and wherein the galvanizing bath, coating weight control device and minispangle box are shown diagrammatically for ease of illustration;

FIG. 2 is a side elevational view of the assembly of FIG. 1 in partial cross-section;

FIG. 3 is an enlarged cross-sectional view of the pre-cooling assembly taken along lines 3--3 of FIG. 2;

FIG. 4 is an enlarged cross-sectional view of the pre-cooling assembly taken along lines 4--4 of FIG. 1;

FIG. 5 is an enlarged transverse cross-sectional view of a pair of opposed nozzles of the pre-cooler assembly as shown in FIG. 4; and,

FIG. 6 is a cross-sectional view taken along lines 6--6 of FIG. 5.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring now to the drawings, wherein the showings are for purposes of illustrating the preferred embodiment of the invention and not for limiting same, FIGS. 1 and 2 show a conveying means employed to convey strip steel 10 or a strip of other material to be treated along a work path W through a galvanizing bath of molten zinc 20, coating weight control device 12, and a natural cooling area 14. The strip steel exits the natural cooling area with a non-uniform temperature across the strip width.

A differential pre-cooler assembly 18 adjacent the minispangle box cools the strip steel non-uniformly across its width in a manner which is complimentary to the temperature distribution thereacross such that the strip steel exits the pre-cooler assembly with a generally uniform temperature. The conveying means conveys the strip steel with uniform temperature from the pre-cooling assembly to the minispangle box. The minispangle box cools the strip further and creates a uniform minispangle appearance on the coating.

Referring to FIGS. 3 and 4, and with continuing reference to FIGS. 1 and 2, the pre-cooler assembly 18 includes a frame assembly 30. A plurality of pairs of nozzle means are mounted to the frame on opposite sides of work path W. Specifically, the pre-cooling assembly includes a first pair of nozzle means 32a and 32b, a second nozzle pair 34a and 34b, a third nozzle pair 36a and 36b, and a fourth or trailing end nozzle pair 38a and 38b. A manifold 40 interconnects all of the nozzle means, and, in the preferred embodiment, the manifold means interconnects the nozzle means with a source of cooling fluid, eg., cool air. It is to be appreciated, however, that the manifold may analogously interconnect the nozzle means with a source of heated fluid such that the nozzle means differentially heat the strip across its width. Further, the manifold may also connect the nozzles with an exhaust means, a source of other cooling or heating fluid, and the like.

With particular reference to FIG. 1, the pre-cooler assembly is moveably mounted such that it is selectively positionable relative to the flow path of conveyed strip 10, or such that it can be removed totally from communication with the flow path. To facilitate mobility, frame 30 includes wheels or casters 42 which roll along parallel spaced apart tracks 44. A first duct section 46 connected with manifold 40 is interconnected with a blower 48 by means of a slip fitting 50. This slip fitting enables first duct section 46 to be telescopically received in a second duct section 52 to accommodate the foregoing movement of pre-cooler assembly 18.

With particular reference to FIGS. 5 and 6, one of the nozzle pairs used in the pre-cooler assembly is shown in detail. Because each nozzle pair is of substantially the same construction, only the pair comprised of nozzles 38a, 38b is described in detail herein. However, it is to be appreciated that the other nozzle pairs are identical thereto unless otherwise specifically noted. More particularly, nozzle means 38a, 38b include fluid conducting conduits 60a, 60b, respectively, communicating with manifold 40. Conduits 60a, 60b, in turn, have arrays of apertures 62a, 62b defined therein.

In the preferred embodiment, each nozzle aperture array is linear in nature and defined by a plurality of evenly spaced circular bores. Moreover, arrays 62a, 62b are disposed on opposite sides of work path W in a facing relationship with each other transversely of the work path. Thus, fluid such as air or the like issuing from the arrays will impinge the opposite sides of strip 10 transversely thereacross. It is to be appreciated, however, that the nozzle aperture arrays may also include one or more elongated slots or other aperture shapes which permit fluid to flow therethrough as described. Perforated plates 64a, 64b are disposed behind the aperture arrays, and each plate is perforated with holes which have a total area substantially larger than the nozzle apertures. Moreover, a sufficient number of holes are included so that plates 64a, 64b are rendered approximately ten percent (10%) open.

Variable nozzle restriction means such as dampers 66a, 66b are disposed in a surrounding relationship with conduits 60a, 60b, respectively, for selectively obstructing the nozzle aperture arrays. As best shown in FIG. 6, the dampers are of a two-piece construction joined by conventional means at central flanges 68a, 68b. However, other constructions could also be satisfactorily employed without in any way departing from the invention. In the preferred embodiment, conduits 60a, 60b and dampers 66a, 66b are circular in cross-section and concentrically mounted such that each damper is rotatable about its associated conduit. As shown, one end of the damper 66b is sleeve mounted to conduit 60b adjacent manifold 40 as at numeral 70b. The other end is shaft mounted to frame 30 as at numeral 71b. Optionally, the conduits and dampers may have other relationships and/or mountings which facilitate relative sliding movement therebetween. For example, conduits 60a, 60b may have flat surfaces adjacent the nozzle apertures and the dampers 66a, 66b may be mounted to undergo linear, sliding movement relative thereto. Such modifications do not depart from the overall intent or scope of the invention.

The dampers have axial slot-like openings including leading edge portions 72a, 72b extending substantially over the lengths thereof which may be selectively moved or rotated across nozzle aperture arrays 62a, 62b, respectively, for restricting fluid passage through predetermined portions thereof. In the preferred embodiment, nozzle aperture arrays 62a, 62b are linear, and damper leading edges 72a, 72b are somewhat U-shaped with opposed, gradually sloping side portions and central portions. FIG. 6 best shows this conformation for damper 66b, it being understood that the other dampers are similar thereto. As damper 66b is rotated clockwise from the fully open position of FIG. 6, the far or outer extremes of the leading edge as designated by numeral 74b begin to cover apertures in array 62b at the outer extremes thereof. With continued clockwise rotation, the nozzle apertures spaced toward the central area of conduit 60b are progressively obstructed. All nozzle apertures are obstructed when the leading edge has rotated to the position designated by numeral 76b. When the leading edge is in an intermediate position, (i) the apertures at the far extremes are totally covered, (ii) the apertures in the central region are unobstructed, and (iii) the apertures in an intermediate region between the central region and the end region are partially obstructed.

Although nozzle arrays 62a, 62b are illustrated as being linear, and leading edges 72a, 72b are illustrated and described as being somewhat U-shaped, it is to be appreciated that other arrangements of the aperture arrays and the leading edges may achieve similar results. For example, the nozzle aperture arrays may extend along an arcuate path and the leading edges may be linear. Alternatively, both the aperture arrays and leading edges may include sloping portions. As yet another option, the leading edges may be castellated, sinusodial, or otherwise irregular, to modify the transition between open and closed nozzle aperture regions.

Nozzle means 38a and 38b are mounted with opposite ends thereof connected to manifold 40. A mechanical interconnecting means generally designated 78 conveniently interconnects the pair of dampers 66a, 66b such that they undergo coordinated movement in which each obstructs substantially the same portion of the associated array of nozzle apertures. As will be best appreciated from FIG. 6, this particular interconnecting means causes damper 66a to rotate downwardly to obstruct the associated nozzle aperture array 62a, and causes damper 66b to rotate upwardly to obstruct the associated nozzle aperture array 62b. The interconnecting means for the other nozzle means pairs are shown in FIG. 4.

Referring again to FIGS. 5 and 6, an electrical drive 80 selectively pivots a lever arm 82 which is connected by a link 84 with the damper 66a such that movement of lever arm 82 opens and closes the nozzle array 62a. An adjustable connection 86 permits selective adjustment of the effective length of the lever arm 82 to vary the relative angular displacement of the damper for a given degree of pivoting of the electrical drive and lever arm. A link 88 interconnects tabs 90a and 90b affixed to the left and right dampers such that both dampers undergo the same degree of angular displacement with movement of the lever arm. This retains the left and right dampers in a coordinated relative position.

In use, the steel strip emerging from the natural cooling area 14 along work path W has an uneven heat distribution. Most commonly, the strip is hotter in the center area and cooler adjacent the outer edges, although the exact temperature distribution will vary with thicknesses of the steel strip and coating and prior thermal treatments of the strip. In that case, the first pair of cooling nozzles 32a, 32b is adjusted so that cooling fluid issuing therefrom cools a central portion of the strip on both sides thereof. As will be appreciated, the variation in cooling capacity across the nozzle pair is frequently different from the heat distribution across the strip. Accordingly, the first nozzle pair will merely bring the strip closer to a more uniform heat distribution upon reaching second nozzle pair 34a, 34b. The nozzles of the second pair are adjusted, frequently different from the nozzles of the first pair, to bring the strip to a still more uniform temperature distribution. Similarly, the third and fourth nozzle pairs are adjusted to render the temperature distribution across the strip even more uniform.

Oftentimes, the temperature distribution can be rendered substantially uniform with four nozzle pairs. If fewer nozzle pairs are required, one or more of the pairs may be closed, or they may be fully opened to cool the strip further without affecting the temperature distribution. Similarly, if the strip does not achieve a satisfactory temperature distribution after passing through four nozzle pairs, additional pairs may be added as deemed necessary.

The invention has been described with reference to the preferred embodiment. Obviously, modifications and alterations will occur to others upon a reading and understanding of the foregoing detailed description of the preferred embodiment. It is intended that the invention be construed as including all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims

1. A pre-cooler assembly adapted for selectively cooling a continuous strip non-uniformly across its width as the strip travels along a work path disposed in operative communication with the pre-cooler, the pre-cooler assembly comprising:

(a) at least a first nozzle means for directing at least a first band of fluid extending generally across the work path and adapted to impinge transversely against a strip moving therealong for adjusting a temperature distribution across the strip width; and,

(b) a first nozzle restricting means for selectively and in a preselected pattern truncating the first fluid band flowing from the first nozzle means in a non-uniform manner transversely of the work path such that the amount of fluid flow adapted to impinge a strip moving therealong is variable across the strip width, whereby selective non-uniform cooling across the strip width may be obtained.

2. The assembly as set forth in claim 1 wherein the first nozzle means includes a first pair of nozzle arrays disposed in a facing relationship on opposite sides of the work path and wherein the first nozzle restricting means includes a damper associated with each of the nozzle arrays.

3. The assembly as set forth in claim 1 wherein the first nozzle means includes first and second tubular conduits operably disposed relative to and on opposite sides of the work path, the first and second conduits defining first and second arrays of nozzle apertures, respectively, extending therealong directed generally toward each other such that the first fluid band and a second fluid band are emitted from the first and second nozzle aperture arrays and impinge against opposite sides of a continuous strip moving along the work path; and, wherein the first nozzle restricting means includes first and second dampers disposed in operative association with the first and second conduits, respectively, for selectively blocking portions of the nozzle aperture arrays to truncate the fluid bands.

4. The assembly as set forth in claim 3 wherein the first and second dampers are operably interconnected such that they cover substantially the same portion of their associated nozzle aperture array.

5. The assembly as set forth in claim 4 wherein each damper has a leading edge which is moveably disposed relative to its associated nozzle array such that the nozzle aperture array is progressively covered from its outer extremes toward a central portion as the leading edge and nozzle aperture array undergo relative motion in a first direction.

6. The assembly as set forth in claim 5 wherein each conduit is substantially circular in transverse cross-section and one of the associated damper is mounted for limited rotational movement therearound.

7. The assembly as set forth in claim 6 wherein each nozzle aperture array includes apertures extending linearly along the conduit, the leading edge of the associated damper having a generally U-shaped conformation for selectively permitting a central portion of the nozzle aperture array to be exposed while covering the outer edge portions.

8. The assembly as set forth in claim 2 further including at least a second pair of nozzle arrays downstream along said work path from said first pair of nozzle arrays and disposed in a facing relationship on opposite sides of said work path, said assembly further including a damper associated with each of the arrays in said second pair, the first and second pairs of nozzle arrays being independently adjustable such that each is adapted to selectively direct fluid against different portions of a continuous strip moving along said work path.