US3439519A - Billet roughing mill - Google Patents

Description

April 22, 1969 c. c. GERDING BILLET ROUGHING MILL Sheet Filed April 25. 1967 iwvmoxi. CHARLES ,C. GERDING hisATTORNEY 4 April 22, 1969 c. c. GERDING 3,439,519

BILLET ROUGHING MILL Filed April 25, 1967Sheet 2 of s- INVENTOR. CHARLES C. GERDING his ATTORNEY Sheet c. c. GERDING BILLET ROUGHING MILL April 22, 1969 Filed April 25. 1967 km Oh INVENTOR. CHARLES C. GEROING his ATTORNEY United States Patent 3,439,519 BILLET ROUGHING MILL Charles Christian Gerding, Pittsburgh, Pa., assiguor to Jones & Laughlin Steel Corporation, Pittsburgh, Pa., a corporation of Pennsylvania Filed Apr. 25, 1967, Ser. No. 633,442 Int. Cl.B21b 21/00, 13/10;B21d 41/04 US. Cl. 72-189 ,11 Claims ABSTRACT OF THE DISCLOSURE A roughing stand adapted to work substantially the entire periphery of a billet. It is provided with peripherally disposed undriven work rolls, each of which is moved in a closed curved path toward and away from the billet by synchronized drive means. The rolls are arranged in sets, each set moves as a unit displaced in time phase with respect to each other set of rolls.

This invention has to do with the rolling of metal blooms and billets. It is more particularly concerned with apparatus for effecting a large substantially symmetrical reduction of a billet in a single pass.

My apparatus is intended to effect the rough reduction of metal billets, blooms and the like. It will be described hereinafter with reference to the hot rolling of steel billets, but it is likewise adapted to the rolling of other metals. It is conveniently employed to work all faces of a billet of conventional square cross-section in a single pass and will be so described hereinafter, but it is adapted to work all faces of billets of other prismatic forms, such as those of hexagonal cross-section, or substantially the entire surface of a cylindrical billet. My ap paratus as adapted to square or rectangular billets employs two pairs of work rolls, each pair consisting of oppositely disposed rolls adapted to work opposite faces of a billet. The pairs of rolls are positioned at right angles to each other so as to work all four faces of a billet in a single pass. My work rolls are freely rotatable on their bearings and are not driven by any external source of power other than the friction exerted by the work itself in the reduction of a billet. The rolls of each pair are moved toward and away from each other in a closed curved path by individual eccentrics which in turn are driven by the mill motor.

Several embodiments of my invention presently preferred by me are illustrated in the attached figures, to which reference is now made.

FIGURE 1 is a vertical cross-section of a first embodiment of my apparatus taken at right angles to the passline on the plane 1-1 of FIGURE 2.

FIGURE 2 is a side elevation of the apparatus of FIGURE 1.

FIGURE 3 is a vertical cross-section taken on the plane 3-3 of FIGURE 2.

FIGURE 4 is a vertical cross-section taken on the plane 4-4 of FIGURE 2.

FIGURE 5 is an end elevation of the essential elements of a second embodiment of my invention partly in section taken on the plane 5-5 of FIGURE 6.

FIGURE 6 is a side elevation of the apparatus of FIGURE 5 partly in section taken on the plane 6-6 of FIGURE 5.

FIGURE 7 is a partial vertical cross-section otherwise like that of FIGURE 3 of a third embodiment of my invention.

FIGURE 8 is a partial vertical cross-section otherwise like that of FIGURE 3 of a fourth embodiment of my invention.

FIGURE 9 is a side elevation somewhat like that of FIGURE 6 of a fifth embodiment of my invention.

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In the figures thepassline 1 is identified by a broken line. The apparatus of FIGURES 1 through 4 is mounted on aframe 2, which is generally elongated in the direction of thepassline 1 and is supported at its ends bylegs 3 and 4.Adjacent end 3,frame 2 is formed with four pairs of outwardly projecting lugs. Lugs 5-5 project upwardly, and opposite to them lugs 6-6 project downwardly. Lugs 7-7 project to one side offrame 2, and opposite them lugs 8-8 project to the other side offrame 2. In FIGURE 1, lugs 7-7 are on the left and lugs 8-8 on the right side offrame 2. In lugs 5-5 is journaled a rotatablehorizontal shaft 9, provided at each of its ends outside lugs 5-5 with bevel gears 10-10. In lugs 6-6 is journaled a rotatable horizontal shaft 11 which is provided at its ends outside of lugs 6-6 with bevel gears 12-12. Shaft 11 continues beyond onebevel gear 12 asshaft 13, which throughcoupling 14, is connected togear reducer 15, which is driven by a motor or other source of power, not shown.

In lugs 7-7 is journaled a verticalrotatable shaft 16, the ends of this shaft outside lugs 7-7 being provided with bevel gears 17-17. In lugs 8-8 is journaled verticalrotatable shaft 18, the ends of which outside lugs 8-8 are provided with bevel gears 19-19. The bevel gears affixed to the ends of thehorizontal shafts 9 and 11 mesh with the bevel gears aflixed to the adjoining ends of thevertical shafts 16 and 18; for example,bevel gear 10 withbevel gear 17, andbevel gear 12 withbevel gear 19.

Between lugs 5-5horizontal shaft 9 is provided with an eccentric 21. Between lugs 6-6 horizontal shaft 11 is provided with an eccentric 22. Likewisevertical shaft 16 between lugs 7-7 is provided with an eccentric 23, andvertical shaft 18 between lugs 8-8 is provided with eccentric 24. Positioned abovepassline 1 iselongated member 26, oneend 27 of which surrounds eccentric 21 and provides a journal therefor. Positioned belowpassline 1 iselongated member 28, oneend 29 of which surrounds and journals eccentric 22. Positioned to the left of the passline iselongated member 30, oneend 31 of which surrounds and journals eccentric 23. Positioned to the right of thepassline 1 iselongated member 32, oneend 33 of which surrounds and journals eccentric 24.

Theother end 35 ofelongated member 26 is pivotally connected to alink 36, which in turn is pivotally connected to projection 37 offrame 2. Theother end 38 ofelongated member 28 is pivotally connected to alink 39, which is pivotally connected toprojection 40 offrame 2. Theother end 41 ofelongated member 30 is pivotally connected tolink 42, which is pivotally connected toprojection 43 onframe 2. Theother end 44 ofelongated member 32 is pivotally connected tolink 45, which is pivotally connected toprojection 46 offrame 2.

Intermediate its ends,elongated member 26 is formed as achannel 48, between the walls of which is journaled freely rotatable work .roll 49. The open end ofchannel 48 faces thepassline 1, and the closed end forms a guard for the work roll within it.Work roll 49 is journaled inchannel 48 so that its workingface 50 isadjacent passline 1 and parallel to the corresponding face of the pass. In like manner freelyrotatable work roll 52 is journaled within thechannel portion 51 ofelongated member 28, so that its workingface 53 isopposite work face 50 ofroll 49. Freelyrotatable work roll 55 is journaled within thechannel portion 54 ofelongated member 30, so that workingface 56 is parallel to one face of the pass, andwork roll 58 is journaled within channel portion '57 ofelongated member 32, so that its workingface 59 is opposite workingface 56 ofwork roll 55.

The operation of this embodiment of my invention will be described with respect to the foregoing description. When power is applied toshaft 13, the arrangement of bevel gears which has been described causes all fourshafts 9, 11, 16 and 18 to rotate in synchronism.Eccentrics 21 and 22 are fastened toshafts 9 and 11 respectively, 180 out of phase with each other, so thatelongated members 26 and 28 are caused to approach thepassline 1 and recede from it synchronously.Eccentrics 23 and 24 are similarly affixed tovertical shafts 16 and 18 respectively, so thatelongated members 30 and 32 likewise approach thepassline 1 and recede from it synchronously. The link mounting of the ends of the elongated members above mentioned permits the elongated members to move in the direction of the passline, as well as perpendicular to it. As the opposite pairs of work rolls are journaled in their respective elongated members, the rolls of each pair approach and recede from the passline synchronously. Theeccentrics 21 and 22 are set 180 out of phase with theeccentrics 23 and 24 respectively, so that work rolls 49 and 52 approach the pass while work rolls 55 and 58 are retreating from it and vice-versa. In this way the billet in the pass is worked first on one pair of opposite faces and then on the other pair of opposite faces, so that it is reduced on all faces in the same pass.

It will be noted that the motion of the eccentrics causes each work roll, such aswork roll 49, to approachpassline 1 in a curved path and retreat from it in a second curved path. The centerline ofwork roll 49 or any other of the Work rolls thus moves in a closed curved path. As work rolls 49, 52, 55 and 58 are mounted for free rotation and are not driven by the mill motor, they are free to rotate about their axes when they make contact with the work in the pass, in the direction determined by the friction of the work roll with the material being reduced and motion imparted to the workpiece by the mill feeding and withdrawing means.

FIGURES and 6 illustrate the essential elements of a second preferred embodiment of my invention. The figures show the arrangement employing single eccentrics located within freely rotating undriven work rolls, but, for clearness, do not show any frame structure, gears, or driving mechanism. These elements have been described in connection with the first preferred embodiment of my invention. The mill comprises four eccentrics disposed in two planes at right angles to each other, as in the case of the embodiment of FIGURES 1 through 4.Eccentrics 60 and 61 mounted on parallel drivenshafts 62 and 63 respectively constitute one such pair. Theouter rim 64 of eccentric 61 is semicircular in cross-section and forms one half of a ball race. Surrounding eccentric 61 is a separate 'freely rotatingrim 65, which constitutes the work roll, theinner surface 66 of which is also semicircular in cross-section and forms the other half of the ball race mentioned above. Therim 65 rotates freely on eccentric 61, supported by a plurality of ball bearings 6767 which are positioned between the ball race surfaces 64 and 66.Eccentric 60 is surrounded by a like freely rotating rim 68 which moves on ball hearings in the same manner as has been described forrim 65. The workingface 70 ofrim 65 is positioned on one side of thepassline 1 opposite to workingface 72 of rim 68. FIGURE 5 illustrates one of the second pair of eccentrics positioned in a plane perpendicular to that ofeccentrics 60 and 61 previously described. This eccentric 75 supports a freely rotatingrim 74 on ball bearings 67-67 in the manner described. The identical eccentric and freely rotating rim mounted thereon positioned opposite eccentric 75 are not illustrated.

The apparatus illustrated in FIGURES 5 and 6 reduces the billet in essentially the same way as that of the previously described embodiment.Shafts 62 and 63 are geared together and rotated by a driving mechanism not shown. Theeccentrics 60 and 61 are set onshafts 62 and 63 re spectively, so as to cause the working faces 70 and 72 of freely rotatingrims 65 and 68 to approach opposite faces of the work and recede therefrom synchronously.Rims 65 and 6-8 rotate freely around theirrespective eccentrics 60 and 61, supported by the ball bearings 67-67.

The other pair of eccentrics likewise provided with freely rotatable rims and positioned in the plane perpendicular to that ofeccentrics 60 and 61 rotate in the same way, driven through gearing 'by the same driving mechanism, but the eccentrics are set so that the working faces of the work rims carried by them approach the billet at the same time the work faces 70 and 72 ofrims 65 and 68 are receding from the billet.

A third embodiment of my invention is illustrated in FIGURE 7. This embodiment is identical with my first embodiment with the exception that the working face 76 ofwork roll 49 is grooved. The same is true of the working faces 77, 78 and 79 of work rolls 52, 55 and 58, respectively. The working faces of the work rolls define a square pass as before but by its corners rather than its sides, and the billet is worked on those corners rather than on its faces.

A further embodiment of my invention is illustrated in FIGURE 8. This embodiment is identical with my first and third embodiments with the exception that workingface 80 ofwork roll 49 is concave and forms an arc of a circle. The same is true of the working faces 81, 82 and 83 of work rolls 52, 55 and 58 respectively. The working faces of the work rolls define a circular pass and the mill rolls round or cylindrical billets.

A fifth embodiment of my invention is illustrated in FIGURE 9. It is not essential that the undriven work rolls of my mill be freely rotatable through the full arc of 360.Shaft 85 and eccentric 86 mounted thereon correspond toshaft 62 andeccentric 60 of the second embodiment of my invention illustrated in FIGURE 6.Undriven roll 87 is mounted on ball bearings 8989 to rotate on eccentric 86.Work roll 87 is provided with a largerdiameter working face 88 which extends around a portion only of its circumference.Roll 87 is restrained in its rotation byspring 90 which is positioned between one shoulder 92 of the workingface 88 andframe 2, and by spring 91 which is positioned between theother shoulder 93 of workingface 88 andframe 2.Springs 90 and 91 yieldingly oppose rotation ofroll 87 through a large arc but do not restrain its rotation through the small arc resulting from frictional engagement of the work roll by the work.

The first preferred embodiment of my invention which I have described is desirable where work rolls of relatively small diameter are to be used. The second preferred embodiment is desirable when work rolls of relatively large diameter are to be used. As the work roll surfaces which make contact with the billet are not driven but are freely rotatable in their mountings, the operation of my mill does not feed the work through the mill. For this purpose a feeding mechanism is necessary, such as a pair of pinch rolls on one or both sides of the mill. My mill will reduce work passed through it whether the work is passed in the direction of rotation of the rolls or in the direction opposite the rotation of the rolls. Because the work rolls of my apparatus are freely rotatable and are not driven, different areas of their work surfaces are brought into contact with the work at different times, and wear on the work rolls is thus equalized.

Although I have described and illustrated the third and fourth embodiments of my invention in terms of my first embodiment, those skilled in the art will appreciate that they could be realized equally well as modifications of my second embodiment. Likewise the fifth embodiment of my invention could be based on my first embodiment rather than my second. Those skilled in the art will also appreciate that my mill is not restricted to reducing a billet of square cross-section, for example, to a billet of a smaller square cross-section, but can also reduce a billet of square cross-section to one of round cross-section or to other non-square cross-section, and vice-versa.

While I prefer to use eccentrics to impart the desired motion to the work rolls of my mill and have described the various embodiments of my invention in that context, I do not intend thereby to exclude other means of effecting the desired motion, such as hydraulic means, for example.

In the embodiments of my invention described herein, two sets of two work rolls each are provided. Each set of rolls is positioned with the roll axes perpendicular to a plane passing through the passline, and those planes are perpendicular to each other. For hexagonal billets my invention employs three sets of two work rolls each or two sets of three work rolls each, each roll being positioned as before with the roll axis perpendicular to a plane passing through the passline, but having the planes disposed at angles of 60 to each other. The work rolls of each set are operated to approach the work and recede from it synchonously and this cycle for each set of work rolls is displaced in time phase with respect to that of each other set. This principle may be extended to the rolling of other multisided prismatic shapes by symmetrical sets of rolls moving against the stock in phased synchronism.

I claim:

1. Apparatus for symmetrically reducing the thickness of a ductile billet in a single pass comprising frame means, a plurality of sets of undriven rotatable work rolls supported by the frame means, the rolls of each set being disposed symmetrically around the passline with the axis of each roll perpendicular to a plane passing through the passline, those planes for each set of rolls being disposed at equal angular intervals around the passline, and the several sets being disposed symmetrically around the passline, first means attached to the frame means causing the work rolls of a set to move in identical closed curved paths in the same direction parallel to the passline and in radially opposed directions perpendicular to the passline and second means attached to the frame means causing the paths of movement of successive sets of work rolls to be displaced in time phase with respect to each other.

2. Apparatus ofclaim 1 in which the work rolls are restrained to permit rotation through an arc of less than 360 and their working faces extend only over that arc.

3. Apparatus ofclaim 1 in which the first means comprise a rotatable eccentric provided around its circumference with antifriction bearing means on which its associated work roll rotates.

4. Apparatus ofclaim 1 in which the number ofsets 6 of work rolls is at least two and the work roll faces are contoured to form a circular pass.

5. Apparatus ofclaim 1 in which the number of sets of work rolls is at least two, and the work roll faces are contoured to form a pass which is a regular polygon having an even number of sides.

6. Apparatus ofclaim 1 in which the first means comprise a rotatable eccentric journaled in the frame means, an element elongated in the direction of the passline, one end of that element surrounding the eccentric and the other end of that element being attached to the frame means by third means permitting movement of the element both parallel and perpendicular to the passline, the element being provided intermediate its ends with journals for a work roll.

7. Apparatus ofclaim 4 in which each set consists of two work rolls.

8. Apparatus ofclaim 5 in which the axis of each work roll is parallel to the edge of the pass adjacent thereto.

9. Apparatus ofclaim 5 in which the axis of each work roll is inclined to the adjacent edges of the pass adjacent thereto.

10. Apparatus ofclaim 5 in which each set comprises two work rolls.

11. Apparatus ofclaim 6 in which the third means comprise link and pin mechanism.

References Cited UNITED STATES PATENTS 802,048 10/1905 Lambert et al 72-190 1,549,527 8/1925 Fielding 72189 3,059,510 10/1962 Appel 72402 3,103,139 9/1963 Saxl 7219O 3,153,955 10/1964 Platzer 72190 FOREIGN PATENTS 225,497 6/ 1962 Austria.

CHARLES W. LANHAM, Primary Examiner.

A. RUDERMAN, Assistant Examiner.

U.S. Cl. X.R. 72190, 225, 402, 452

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