1. Field of the Invention
The present invention relates to a descaling method and a descaling apparatus, more particular to a descaling method and a descaling apparatus that apply high-pressure fluid to remove the scale on the surface of semi-finished products (referred as rolling stock) in the hot rolling processes, such as the rolling of steel strip, steel plate, shaped steel, steel bar, wire rod, etc., for descaling purpose.
2. Description of the Related Art
In general, the scale on the surface of the rolling stock must be removed preceding rolling to prevent from the rolled-in-scale defects in a conventional hot rolling process such as for steel strip or steel plate. Therefore, a high-pressure fluid descaling apparatus is usually arranged before the rolling machine.
a) shows the schematic drawing of the impact regions formed by the ejection of the nozzles of the conventional high-pressure fluid descaling apparatus;
As shown in
As shown in
The blank region (G) occurs mainly because the rebounding fluid 16 from the jet curtain 13 behind the overlapped region interferes with the jet curtain 12 ahead of the overlapped region as shown in
In the blank region (G), only slight mark appears. In the softened region (W), rough surface is formed on the aluminium testing plate, whereas the width and depth of the erosion mark becomes narrower and shallower. In other words, the impact force or descaling effect to the blank region (G) and the softened region (W) is diminished due to the interference caused by the rebounding of the jet sprays from the adjacent nozzles.
The existence of the blank region (G) and the softened region (W) shows that the conventional high-pressure fluid descaling nozzles 11 are not adequately arranged, which is one of the main reasons why the scale is rolled in. However, in respect to the conventional technology, the problems are often deemed improper arrangement of the nozzles 11 or improper arrangement of the descaling apparatus, which causes the insufficient overlap of the impact regions 14 and 15.
Therefore, it is innovative to provide a high pressure fluid descaling method and apparatus for the hot rolling process to reduce the interference on the overlapped region, in which the rebounding fluid emerged from the jet curtains of the adjacent nozzles.
The present invention is directed to a high-pressure fluid descaling method and apparatus applied in hot rolling process, wherein the apparatus comprises at least one descaling unit, the at least one descaling unit comprising a main pipe header and a plurality of nozzles, wherein a projection of an axial direction of the main pipe header on a surface of the rolling stock and a rolling stock transportation direction intersects, and the main pipe header is used to supply a jet fluid. The nozzles are arranged on the main pipe header. Each nozzle is orientated towards a direction opposite to the rolling stock transportation direction so as to erode the scale off the surface of the rolling stock. The jet fluid ejected from the nozzles forms a plurality of impact regions on the surface of the rolling stock, of which the regions are alternately parallel to each other. The center lines of the impact regions along the longitudinal direction of the regions are evenly spaced apart and perpendicular to the rolling stock transportation direction.
The high-pressure fluid descaling method and descaling apparatus applied in hot rolling process according to the present invention can reduce the interference caused by the rebounding fluid from the jet curtains of the adjacent nozzles, thereby improving the descaling quality and reducing the scale on the surface of the rolling stock, which in turn improves the quality of the surface of the products. In practice, the invention can be applied to the hot rolling process such as to the steel strip, steel plate, shaped steel, steel bar and wire rod.
a) shows the schematic drawing of the impact regions formed by the ejection of the nozzles of the conventional high-pressure fluid descaling apparatus;
b) shows the schematic drawing of the arrangement of the conventional high-pressure fluid descaling apparatus;
c) shows the side view of a conventional high-pressure fluid descaling apparatus;
a) shows the schematic drawing of the impact regions formed on the surface of the rolling stock by the jet curtains of the nozzles of the hot rolling high-pressure fluid descaling apparatus, according to a first embodiment of the present invention;
b) shows a schematic drawing of the arrangement of the descaling nozzles of the hot rolling high-pressure fluid descaling apparatus, according to the first embodiment of the present invention;
c) shows a side view of the hot rolling high-pressure fluid descaling apparatus, according to the first embodiment of the present invention;
a) shows a schematic drawing simulating the impact regions formed on the surface of the rolling stock by the jet curtains of the nozzles of the hot rolling high-pressure fluid descaling apparatus, according to a first embodiment of the present invention;
As shown in
The nozzles 22 are arranged on the main pipe header 21. Each nozzle 22 is orientated towards a direction opposite to the rolling stock transportation direction; i.e., the direction of descaling jet by high-pressure fluid is opposite to the rolling stock transportation direction. In the embodiment of the invention, the nozzles 22 comprise a plurality of first nozzles 221 and a plurality of second nozzles 222 adjacent to the first nozzles 221.
The first nozzles 221 and the second nozzles 222 eject the fluid onto the surface of the rolling stock 3 so as to form a plurality of first impact regions 31 and a plurality of second impact regions 32 adjacent to the first impact regions 31, in which the two regions are alternately parallel to each other. The first impact regions 31 and the second impact regions 32 are overlapped in the rolling direction on the surface of the rolling stock 3. The center lines of the regions along the longitudinal direction of the regions are evenly spaced apart with a distance D and are perpendicular to the rolling stock transportation direction.
In the embodiment, the first nozzles 221 and the adjacent second nozzles 222 are spaced apart along the axial direction of the main pipe header 21 and arranged alternately; that is, the first nozzle 221 ejects jet curtain 23 and the adjacent second nozzle 222 ejects jet curtain 24, which form the impact region 31. The impact region 32 will be produced in the next impact area arranged by the consecutive nozzles. The nozzle and its adjacent nozzle will be arranged alternately. Hence, the impact regions occur respectively. (see
The positions of the first nozzles 221 and the second nozzles 222 may be arranged in a way that the center lines 223 of the first nozzles 221 and the center lines 224 of the adjacent second nozzles 222 are parallel to one another and symmetric to the radial line 212 passing through an axis of the main pipe header 21 (as shown in
In the arrangement where the center lines 223 of the first nozzles 221 and the center lines 224 of the second nozzles 222 are parallel to one another, D is the distance between the first impact regions 31 and the second impact regions 32; whereas, D′ is the distance between the first nozzles 221 and the second nozzles 222, and β is the inclination angle that is between the center line of the first nozzles 221/the second nozzles 222 and the normal line of the surface of the rolling stock. The relation would be D′=D cosβ.
Alternatively, the positions of the first nozzles 221 and the second nozzles 222 may be arranged in a way that their corresponding center lines would not be parallel to one another. In this case, their center lines 223 and 224 may or may not intersect the axis 211 of the main pipe header 21 along the longitudinal direction (as shown in
In the arrangement, D is the distance between the first impact regions 31 and the second impact regions 32; whereas, H is the distance from the surface of the rolling stock to the intersection of center lines 223 and 224. β1 is the first inclination angle between the center line 223 of the first nozzle 221 and the normal line of the surface of the rolling stock; whereas, β2 is the second inclination angle between the center line 224 of the second nozzle 222 and the normal line of the surface of the rolling stock. The relation would be D=H(sinβ1-sinβ2).
Moreover, as shown in
The extended portion 5 added to each single nozzle is more suitable for the larger distance between nozzles 22; whereas, the extended portion 5 added as a lump unit to more than one nozzle 22 is more suitable for the smaller distance between nozzles 22.
It is understood from Formula (2) that the greater the nozzle distance E is, the wider the blank region G is and vice versa. One can also find from Formula (2) that the greater the offset angle γ is, the wider the blank region G is and vice versa.
When the offset angle γ approaches zero (γ≈0), one can deduce from Formula (3) that
G=DtanX (4)
The width of the blank region G depends on the diverging angle X of the rebounding fluid and the distance D between the impact regions 31 and 32.
It is derived from Formula (4). When D≈t (as shown in
G=ttanX (5)
The width of the blank region G is to the minimum theoretically. Yet, due to the errors accumulated from the manufacturing, assembling and the installing of the whole descaling unit 20, the distance D between the impact regions may become smaller than t. The jet spray 23 and the jet spray 24 may also interfere with each other, thereby increase the width of the blank region G. As described previously in the present invention, the relationship between the parameters t, D and E is preferred to be regulated as following:
t<D≦Esin15°.
Table 1 is a comparison of erosion experiments by the descaling apparatus between the present invention and the conventional one.
One can find in the Table 1 that the width of the blank region G is obviously reduced in the present invention compared with that in the conventional test. Hence, the arrangement of the nozzles 22 of the descaling apparatus 2 according to the present invention can effectively improve the descaling quality.
The present invention is also a method applicable to hot rolling high-pressure fluid descaling practices. In the embodiment, the hot rolling high-pressure fluid descaling apparatus 2 is used to conduct hot rolling descaling as shown in
The first impact regions 31 and the adjacent second impact regions 32 are essentially parallel to one and another and distributed alternately on the surface of the rolling stock 3. The impact regions 31 and 32 overlap along the rolling stock transportation direction, of which the center lines of the impact regions along the longitudinal direction are spaced apart with a impact distance D. The longitudinal direction of the impact regions is essentially perpendicular to the rolling stock transportation direction. Preferably, the fluid is ejected onto the surface of the rolling stock 3 through the nozzles 22 with a inclination (lead) angle between 5° and 45°.
The hot rolling high-pressure fluid descaling method, according to the present invention, may also apply the hot rolling high-pressure fluid descaling apparatus 6 with two rows of descaling units 20 to conduct descaling for the rolling stock 3 as shown in
For the hot rolling high-pressure fluid descaling method and descaling apparatus, according to the present invention, when the offset angle approaches zero and the width of the original overlapped impact region is unchanged, the descaling impact force can be enhanced by reducing the spray angle; alternatively, the distance between nozzles can be increased to reduce the number of the nozzles being arranged, hence save the consumption of descaling fluid and improve the descaling efficiency.
The hot rolling high-pressure fluid descaling apparatus, according to the present invention, may have one descaling unit or two descaling units, which may be applied for the removing of scale before the rolling machine, the mill descaling PSB (Primary Scale Breaker) or FSB (Finishing Scale Breaker) so as to enhance the descaling. The hot rolling high-pressure fluid descaling apparatus, according to the present invention, forms the impact regions on the surface of the rolling stock, which are parallel to one another. The interference caused by the rebounding fluid from the jet sprays of the adjacent nozzles is reduced to the minimum, so as to reduce the width of the blank region. Moreover, when the descaling apparatus comprises two rows of descaling unit, the center lines of the nozzles in the front descaling unit are preferably arranged one half of the nozzle distance E offset to the corresponding nozzles in the rear descaling unit, which solves the problem of the blank regions produced via the interference of the jet sprays from the adjacent nozzles.
Therefore, the hot rolling high-pressure fluid descaling method and descaling apparatus, according to the present invention, can improve the descaling quality, reduce the roll-in-scale in the surface of the products and therefore improve the surface quality of the products. In practice, the hot rolling high-pressure fluid descaling method and descaling apparatus, according to the present invention, can be applied to the hot rolling processes such as for steel strip, steel plate, shaped steel, steel bar and wire rod.
While several embodiments of the present invention have been illustrated and described, various modifications and improvements can be performed by those skills in the art. The embodiments of the present invention are therefore described in an illustrative yet not restrictive sense. The intention is that the present invention should not be limited to the particular forms as illustrated, and all the modifications that maintain the spirit and the scope of the present invention are within the scope of the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
100106326 A | Feb 2011 | TW | national |
Number | Date | Country |
---|---|---|
201537629 | Aug 2010 | CN |
1900449 | Jul 1997 | EP |
1900449 | Jan 2010 | EP |
62-050812 | Mar 1987 | JP |
5-084406 | Nov 1993 | JP |
09-308909 | Dec 1997 | JP |
10-263677 | Oct 1998 | JP |
09-174137 | Mar 2008 | JP |
2008-221328 | Sep 2008 | JP |
2010-264498 | Nov 2010 | JP |
Entry |
---|
Office Action dated Feb. 26, 2014 by TIPO for the corresponding TW Patent Application No. 100106326. |
Search Report issued on Feb. 26, 2014 by TIPO for the corresponding TW Patent Application No. 100106326. |
English translation of the Search Report issued on Feb. 26, 2014 by TIPO for the corresponding TW Patent Application No. 100106326. |
Office Action on Nov. 19, 2014 by TIPO for the corresponding TW Patent Application No. 100106326. |
Office Action and the Search Report issued on May 29, 2013 by TIPO for the corresponding TW Patent Application No. 100106326 which cite JP2010-264498A, EP1900449B1, JP2008-221328A, and CN201537629U. |
Office Action for KIPO counterpart application No. 10-2012-0019111 issued on Aug. 22, 2013 (with English translation) citing: JPH09-174137 (with English translation to Abstract), and EP1900449 (with English translation to Abstract). |
Office Action for JP counterpart application No. 2012-037483 issued on Aug. 29, 2013 (with English translation) citing: JPH5-084406U, JPH9-308909A (with English translation to Abstract), and JPS62-050812U. |
Number | Date | Country | |
---|---|---|---|
20120216839 A1 | Aug 2012 | US |