SCLMSTR the Standard in Descaling Technology
Optimal Descaling for Higher Product Quality and Low Maintenance Costs Primary and secondary scale ruin considerably the surface quality of ingots, slabs, blooms, plate bars, sheet metals, strips, profiles and pipes. Not only is the rolling stock surface affected but scale also causes high wear to the rolls. To fight scale effectively, Lechler has developed the SCL MSTR nozzle. It focuses water to a razor sharp, extremely high jet impact stream which guarantees optimal descaling. nd optimal descaling provides: n perfect surface quality n high product quality n low maintenance costs n low roll wear For many years Lechler has been a leader in the design and development of descaling nozzles. By working closely with renowned rolling mills Lechler has consistently achieved many improvements to descaling, always tailored to the exact needs of the users. May we help you? Our technical services group is committed to providing not only the best products but also the finest service to you. 2
Improved Measurement Techniques the Basis of Optimal Nozzle Design Our extensive, partly self dev e - loped measuring instruments have contributed to accurate and precise infor ma tion to aid the development and design of Lechler nozzles. Using these techniques, reliable data on volume, pres sure, impact force and droplet size can be acquired in the design phase of nozzles. This data is used directly in the development process to optimize product design and manufacture. n important factor in the design and evaluation of descaling nozzles is impact and distribution. For the first time, our computer aided measuring instrument can represent this in three dimensions. More exact than the traditional two-dimen sional representation, the 3D-dia g ram shows clearly the exact quantity and quality of impact across the entire impact area. Three-dimensional representation of jet impact distribution product no.:.xxx.27 spray width: 114.0 mm pressure: 240.0 bar total force: 23.0 N flow rate: 69.0 l/min average impact lav: 0.32 N/mm^2 height: 10 mm average depth:.9 mm medium: water SCLMSTR Y Z X Standard Nozzle Comparison of impact areas Spray impact measurement device Spray pattern of a SCLMSTR nozzle Computer controlled data preparation 3
SCLMSTR the conomic Descaling Nozzle Improved product quality, plant efficiency and reduction of energy and water are vital prere - quisites of modern rolling mills. The answer to those needs for your descalers is the SCLMSTR. With the development of the SCL MSTR Lechler once again lives up its innovative reputation in descaling and provides a major advance ment in gaining worldclass surface finish. The SCLMSTR combines the advantages of many nozzle designs in a single package. It is based on the experience gained over a hundred years of nozzle design, combined with the latest research in nozzle technology. Better Surface Quality The razor sharp SCL - MSTR slices through primary and secondary scale faster and more thoroughly than ever. The high impact jet is uniformly distributed eliminating surface streaks. This results in an absolutely clean, smooth surface over the entire width of the strip. 47 1 Hex 36 Ø 42 1 BSPP 40 22 16. Hex 24 hexagon socket Lower nergy and Water Consumption Compared to traditional nozzles, the SCL MSTR uses up to 30% less water and can operate at lower pressures. Consequently, the required pump capacity is considerably reduced. This translates into both lower operating costs for energy and lower capital outlays for pumps. Further more, with the built-in filter available on the SCLMSTR, you may save preliminary filtering costs. Long Life and asy Handling The SCLMSTR is built to stand up the harshest mill conditions. The tungsten carbide tip can withstand the highest pressures, poor water quality and abrasive particles. When a nozzle must be changed, the SCLMSTR is designed to make it both fast and foolproof. The tip, stabilizer and filter can be preassemb - led and then assembled to the header as one unit. By assembling this single unit rather than separate parts, the installation can be performed with one hand and helps maintenance personnel install the nozzles quickly in the most difficult locations. The self align ment feature of the nozzle ensures that the cap can be tightened only when alignment is achieved. Special version of nut, with hexagon socket 4
Nozzle rangement on a Descaling Header Positioning of nozzles on a spray header = C - D C = cos γ B β =, 10 or 1 = spray length B = spray width C = spray width in rolling direction D = over lap = nozzle distance h 2 = vertical spray height α = nozzle spray angle β = angle of inclination γ = offset angle of nozzle against pipe roll axis Jet lenght (), Jet width (B, C), overlapping (D), nozzle distance () and vertical spray height (h 2 ), angle of inclination β = 1, offset angle γ = 1 and nozzle spray angle (α). Vertical spray height h 2 100 10 17 200 22 20 270 300 angle of inclination β = 1 104 1 11 207 233 29 20 311 B 42 40.9 62 9. 72 69.4 2 79.0 92.7 102 9.2 109 10.4 132 127.4 Nominal nozzle spray angle α at p = 10 bar α = 22 α = 26 α = 30 α = 40 C D B C 3.9 1) 4. 64.4 74.0 3.7 90.2 97.4 119.4 60 1 91 100 109 119 126 137 7.7 7.3 7.6 96.6 10. 114.3 121. 132. D B C 1) Only MiniSCLMSTR 2) Standard SCLMSTR only with hexagon socket nut 44.9 1) 73.3 2.6 91.6 100. 109.3 113. 124. 69 94 106 117 12 139 14 161 66.3 90.9 102.2 113.0 123. 134.0 124.4 1.2 D B C 61.3 2).9 97.2 10.0 11. 126.0 134.4 147.2 90 126 142 1 174 19 202 221 7.2 121.2 137.1 12.4 167. 12.4 194.4 212. D 10 10 12 12 1 2.2 113.2 129.1 142.4 17. 170.4 12.4 197. xplanation of the table: 1. Spray width: The listed values are based on p = 10 bar spray pressure. The convergence of the jets is considered in the values of the table. Spray width data for other spray pressures is available on request. 2. Tolerances of the spray angles: + 3 at α = 22, 26 and 30, + at α = 40. Therefore, B + C are minimum values.
Nozzle Position Nozzle ssembly Nozzle Position Options 1. ll nozzles offset in one direction. (see fig. 1) 2. ll nozzles offset toward the nearest outside edge sprays directed away from the center of the strip. This results in better drainage and it is easier to guide the strip. (see fig. 2) Nozzle rrangements To guarantee the correct align ment of the nozzle tip (1 degree offset - see fig. 1,2), the weld base must be positioned on the spray header such that the flats on the tip are parallel to the header longitudinal axis. We recommend you do this with our alignment tip (fig. 1,2,4). It ensures proper positioning of the base during welding. Referring to fig. 3 below, alignment tips are inserted into the base. Then a strip edge is used to easily position and weld each base. One-handed Nozzle ssembly Descaling headers are often located in areas where it is difficult to reach every nozzle. This is particularly true of nozzles located underneath the rolls where you can often reach the nozzle with one hand only. The SCL MSTR nozzle has been designed to ensure easy assembly in those locations by doing most of the assembly prior to installation. The tip, stabilizer and strainer are assembled as one unit. This assembly unit is then inserted into the base and rotated until the flats are aligned allowing further insertion and cap thread engagement. Thread engagement cannot take place until alignment is accomp lished. The cap should not be tightened to more than 20 Nm (1 ft. Ibs.) of torque in order to prevent damage to the tip. fig. 1 fig. 2 Ordering No. 069.490.01.00.00.1 lignment tip Ordering No. Ordering No. Ordering No. 069.490.01.01.00.0 069.490.01.0.0 069.490.01.00.00.1 utomatic djustment of the Nozzle Tip The required 1 degree offset is integrated into every nozzle tip. Consequently, assembling the nozzle tip incorrectly is absolutely impossible. When changing tips, you can be assured that once the cap is tightened down, the nozzle is in the precise position required for it to perform correctly. quipment The alignment tip (fig. 1,2,4) can also be used as blind tip for blanking off specific nozzle positions or for pressure testing the entire spray header. lignment tips 1 1 General Information 1 1 Flow Requirements The flow velocity should not exceed 1 ft./sec. in the water mains and 3 ft./sec. in the descaling headers. Nozzle Control Nozzles are subject to wear. The condition of the water and the environment can both affect nozzle life. Therefore, a regular nozzle inspection pro - gram should be estab lished to ensure proper perfor mance of the nozzle at all times. The intervals for such a program must be established at each installation. Factors such as solid contents in the water can cause wide variations in nozzle wear rates. fig. 3 Positioning of welding nipples with blank tip fig. 4 lignment tip, blank tip Ordering No. 069.490.01 6
Technical Data Volume Flow Table Order Details Series Ordering No. Code Spray angle Mat.-No. Tungsten carbide 22 26 30 40 27 49 496 497 49 3 36 37 3 Stainless steel hardened 11 [l/min] 1 1.00 p = 100 bar (140 psi) [US Gall./min] 3.17 3.96 Flow rate for water (V. ) [l/min] 16.97 21.21 p = 200 bar (2900 psi) [US Gall./min] 4.0.60 [l/min] 24.00 30.00 p = 400 bar (00 psi) [US Gall./min] 6.34 7.92 Volume rate conversion formula:. p 2. V 2 = * V 1 [l/min] p 1. 2)2 p =(V 2. * p 1 V [bar] 1 6 66 67 6 1.00 4.76 2.46 6.73 36.00 9.2 60 64 606 646 607 647 60 64 2 6.0 7.40 32.3 39.60 9.39 10.46 46.00 6.00 12.16 14.0 Ø 42 G1 1 ISO BSPP 22 6 66 67 6 36.00 9.1 0.91 13.4 7 19.02 72 726 727 72 4.00 11.9 63.64 16.1 90.00 23.7 22 76 766 767 76.00 1.32 2.02 21.67 116.00 30.64 47 0 06 07 0 7 19.02 101.2 26.90 144.00 3.04 1 16. 4 46 47 4 9.00 23.1 12.7 33.2 17.00 47.02 6 7 11 29.9 1.39 41. 224.00 9.1 SW Hex 36 36 - - 906 916 907 917 90 91 1 134.00 33.03 3.40 176.7 19.0 46.70 0.07 20.00 26.00 66.06 70.0 40 Hex SW 24 (innen) Hexagon socket xample Series + Code + Mat.-No. = Ordering No. for Ordering: + 49 + 27 =.49.27 Special nut with hexagon socket. For very short spray heights. Ord.-No.: 069.402.11 Dimensions (Spray angle 22 ) (Spray angle 26 ) (Spray angle 30 ) (Spray angle 40 ).49 1.20 1.0.496 1.17 1.0.497 1.16 1.0.49 1.11 1.0.3 1.40 1.7.36 1.30 1.7.37 1.30 1.7.3 1.20 1.7.6 1.60.66 1.0.67 1.40.6 1.20.60 1.0.606 1.70.607 1.60.60 1.0.64 2.0.646 1.90 2.0.647 1.0 2.0.64 1.60 2.0.6 2.20 2.0.66 2.20 2.0.67 2.0.6 2.0.72 2.0.726 2.40.727 2.30.72 1.90.76 2.0 3.0.766 2.0 3.0.767 2.40 3.0.76 2.30 3.0.0 3.20 3.0.06 3.0.07 2.90 3.0.0 2.70 3.0.4 3.0 4.30.46 3.0 4.30.47 3.20 4.30.4 4.30. 3.90 4.70.6 3.90 4.70.7 3.70 4.70. 3.40 4.70.906 4.00.00.907 3.90.00.90 3.70.00.916 4.20.20.917 4.00.20.91 3.0.20 = equivalent bore diameter = narrowest cross section 7
Technical Data Individual Components Ordering Numbers Lechler GmbH Precision Nozzles Nozzle Systems P.O. Box 13 23 7244 Metzingen / Germany Phone: +49 (0) 71 23 962-0 Fax: +49 (0) 71 23 962-333 -Mail: info@lechler.de Internet: www.lechler.com Design without filter Design with filter Ø 43. Ø 43. 10 10 Welding nipple Material: ISI 304 L Jet stabilizer with filter* Material: ISI 303 L Jet stabilizer with cap* Material: ISI 303 16 Nut Material: 430 F ISI 16 L 120 with jet stabilizer 069.4.16 16 with jet stabilizer 069.44.16 - Flat jet nozzle 100 73 36 63 16 43 Welding nipple Jet stabilizer with cap S S F * max. torque: 30 Nm (22 ft.lbs.) (all dimensions in mm) L Jet stabilizer with filter Gasket Flat jet nozzle Nut Component Welding Nipple Material: ISI 304 Jet Stabilizer Material ISI 303 Gasket Material: Copper Nozzle Nut (Hex 41) Material: ISI 430 F lignment Tip Blank Tip Material: Mild Steel Tip extractor Material: ISI 440 B xtraction tool Model Length L = 120 mm L = 100 mm L = 73 mm without filter, with cap S = 74 mm with filter S F = 130 mm S F = 110 mm Data sheet on request Data sheet on request Max. permissible operating pressure: 40 bar Order No. 069.411.1C.00 069.410.1C.00 069.410.1C.73 069.431.16 069.4.16 069.44.16 09.01.34.04.02.0.XXX.XX see table page 7 069.400.11 069.490.01 069.492.1.10.0 09.009.00.12.6.0 Weight (kg) 0.3 0.69 0.4 0.11 0.22 0.19 0.004 0.0 0.13 0.072 0.20 0.9 dition 03/14 N 00 M-2014-30-034 www.dgm-walliser.de S Subject to technical modifications.