US2366087A - Machine for making tubular structures - Google Patents
Machine for making tubular structures Download PDFInfo
- Publication number
- US2366087A US2366087A US445600A US44560042A US2366087A US 2366087 A US2366087 A US 2366087A US 445600 A US445600 A US 445600A US 44560042 A US44560042 A US 44560042A US 2366087 A US2366087 A US 2366087A
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- United States
- Prior art keywords
- mandrel
- spiral
- coils
- shaft
- sleeve
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H81/00—Methods, apparatus, or devices for covering or wrapping cores by winding webs, tapes, or filamentary material, not otherwise provided for
- B65H81/06—Covering or wrapping elongated cores
- B65H81/08—Covering or wrapping elongated cores by feeding material obliquely to the axis of the core
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/51—Plural diverse manufacturing apparatus including means for metal shaping or assembling
- Y10T29/5185—Tube making
Definitions
- This invention relates to machines for making tubular structures and more particularly to a machine for forming tubing comprising an inner spiral supporting member and a covering member preferably wrapped about the supporting member and it is an object of this invention to provide a machine of the class described of improved construction and by which all steps of making such a tubular structure may be performed so as to produce a continuous tubular structure. It is also an object of this invention to provide a machine of the class described of. simple and efllcient construction and which may be easily operated and maintained.
- Figure 1 is a top plan view of a tube forming machine constructed in accordance with this invention.
- Figure 2 is a partial view in side elevation of the machine shown in Figure 1, some parts being broken away to show other parts more clearly;
- Figure 3 is apartial view, partly in vertical section of a machine such as is shown in Fi ures 1 and 2, the view being taken on the longitudinal axis of the machine and showing a section of a machine for making a tube of relatively larger diameter than the machines of Figuresl and 2;
- Figure 4 is a partial vertical sectional view drawn toa larger scale showing. parts of the machine adjacent to the parts shown in Figure 3 and forming acontinuation of the showing of Figure 3;
- FIG. 5 is a fragmentary view in elevation showing the driving mechanism at the left end of the machine as shown in Figures 1 and 2;
- Figure 6 is a view in elevation of the means W supporting the gearing shown in Figure 5, shown detached from the machine and stripped of the Bearing;
- FIG. 7 is a fragmentary vertical sectional view taken as on line 1-1 of Figure 3 and showing..,in side elevation the means for applying an of means 01. modified construction for applying pressure to the coils of the spiral;
- Figure 11 is a sectional view taken as on line il-ll of Fig. and showing on elevation the means for applying pressure to the coils of the spiral.
- a machine in accordance with this invention is shown as comprising a suitable frame having spaced vertical supporting memhere l, la, 2, 2a, 3, 3a, 4 and 4a joined "by upper longitudinal members 5, 6, lower longitudinal members I, 8 and upper and lower transverse members.
- the upper longitudinal members 5, 6 are cut away between the. vertical supporting members 20, la, and 2, 3, respectively.
- the upper longitudinal members 5.6 are joined at the vertical supporting members 2, 2a, by an irregularly shaped plate Ill which serves to support a journal box or bearing l2.
- Rotatably mounted in the bearing I2 is a tubular nut orbox I having an internal spiral groove i5 extending from a tangentially arranged leading-in passage ii at one end of the nut It to the opposite end of the nut.
- a sprocket l1 fixed on an end of the nut i4 and connected by a chain l8 to a corresponding sprocket fixed on a drive shaft 20 serves to drive the nut it.
- the drive shaftill is journalied in bearings mounted on the lower transverse members of the frame and has. at one end, the usual fast and loose drive pulleys 2
- a mandrel 22 which projects at both ends of the nut ll. As shown in Figure 3, the mandrel projects but a short distance to the right of the nut ll while it projects to the left sufliciently to serve as a support for the spool 24 of wire or other metallic strip material of and longitudinal movement.
- the bracket 26 is adjustable frictional resistance to the movement oi the coilslongitudinally of the mandrel;
- Figure 8 is an end view showing the arrangement of the tube supporting and guiding rolls shown in Figures 1, 2 and 4;
- Figure 9 is a substantially. diagrammatic view in side elevation of the take-up rolls for drawing the finished tubing from the machine;
- Figure 10 is a fragmentary plan view showing the application to the machine of Figs. 1 and 2 split at its lower end and'the separated portions may be drawn together by means of a bolt 21 so as to permit of the bracket being secured on a stud 28 mounted in the upper transverse member 8.
- the upper end of the bracket 26 is formed of two portions. one portion 26a being integral with the remainder of the bracket and having a bolt 29 pivotally mounted at its upper end while the other portion 26b is pivotally connected at one end to the main portion of the bracket 26, as at 28c, and is forked at its other 43 on theprojecting end to receive the bolt 29.
- the bracket portions 26a and 26b fit into the groove in the end of the mandrel 22 and, when drawn together by the winged nut 29a on the bolt 29. hold the mandrel in fixed position.
- a stud 39 mounted in the bracket 26 is a stud 39 on which is journalled a gear 32 driven by'a gear 34 and driving a gear 36.
- the gear 34 is journalled on the stud 28. and is attached to a sprocket 33 driven by a chain 35 from a corresponding sprocket 31 fixed on the drive shaft 28.
- the gear 36 is fixed on the reduced end 38a of a threaded shaft 38.- The threaded shaft abuts an end of the mandrel 22 and has its reduced end portion 38a extending through the mandrel 22 to receive the gear 36.
- the gear 36 is of less diameter than the adjacent end of the mandrel 22 so that when the bracket 36 is released from the mandrel 22 and rotated slightly on the stud 28, carrying the gear 32 from the gear 36, the spool 24 can be removed from the mandrel without necessitating removal of the gear'36 from the shaft 38, thus providing for the replacement of empty spools with a minimum of dismantling of the machine.
- the main body portion of the threaded shaft 38 is rotatably mounted in a sleeve 40.
- the sleeve 40 which abuts the end of the nut I4, overlapping the adjacent end of the mandrel 22, extends to the end'of the main body portion of the shaft 38 .and tapers gradually in, thickness from a point intermediate its length.
- the sleeve 48 is mounted to rotate with a bracket support 42 journalled in a bearing 44 mounted on the plate Ill.
- the bracket support 42 is rotated by means of a gear 46 fixed to the bracket support 42 and driven by a pinion 41.
- the pinion 41 is fixed on a shaft journalled in a bearing 48 mounted on the plate I and this shaft has fixed thereon a sprocket 49 driven by, a chain 59 from a vsuitable sprocket fixed on the drive shaft 20.
- a support 51 which has a tubular journal 51a permitting the passage of the tube and supported in a bearing 58 carried by the upper transverse member II of the frame.
- the support 51 is rotated by means of a sprocket 59 fixed on the journal 51a and connected by a chain 60 to a corresponding sprocket fixed on the drive shaft 28.
- or other suitable strip metallic material passes from the spool 24 around a guide roller 62 carried by an arm I4a mounted on the nut I4. From the guide roller the wire 6
- the nut I4 is provided with an arm
- wire coils will be advanced uniformly along the mandrel 22 by the nut I4 until the end on an extension 42a of the bracket support 42,
- bracket arms 52 having, at one end, an axle supporting a roll 54 of suitable wrapping material and, at the other end, a second roll or a counterweight 55 of suitable proportions.
- a screw 53 passing through a slot in the arms 52 and engaging in a threaded opening in the extension 42a serves to retain the arms 52 in adjusted position.
- the arms 52 may be jointed, as at 52a, to provide for adjustment of the roll 54 in each of two directions.
- the main body portion of the threaded shaft 38 is of uniform diameter for the full length of the sleeve 40 and has a cylindrical portion-38b of reduced diameter projecting beyond the sleeve 40.
- secures an externally threaded sleeve portion 38b.
- a dowel engaging the adjacent ends of the main body portion of the shaft 38 and the sleeve 43 secures the sleeve 43 in a predetermined position with respect to the shaft 38 and prevents relative rotation of the shaft and sleeve.
- the sleeve 43 is formed with a plurality of external spiral grooves, one of which forms a continuation of the groove of the shaft 38 and receives the wire or metallic strip forming the interior spiral of the tube.
- the other of the grooves is deeper than the first groove and provides space to permit of corrugating the tube by means of a suitable wire or cord 5I which is wrapped about the tube between the coils of the inner metallic spiral and serves to corrugate the tube and secure the wrappings in position.
- is supplied froma spool 56 of the nut I4 is reached whereupon the advance of the coils is slowed as theirfurther movement along the mandrel is dependent upon the delivery of additional coils of the wire from the nut I4.
- This delivery of additional coils from the nut I 4 gradually forces the coils forward on the mandrel 22 to be engaged in the grooveof the threaded shaft 38.
- a lever 25 pivotally connected at one end, as at 25a, to the ring I9 outer end of the plunger 23.
- the lever 25 is provided with an opening to receive freely a bolt 3
- is threaded to adjustably receive a nut 3
- the threaded shaft 38 is operated at the same speed of rotation as the nut I4 ,so that the coils are removed from the end of the mandrel 22 by the shaft 38 as fast as they are supplied by the nut I4.
- Rotating with the sleeve 48 is the spool 54 of any suitable wrapping material 63 which 'is wrapped about the sleeve 40, the number of layers provided being varied as required by varying the width of the wrapping material, speed of rotation about the sleeve and the angle at which the material issupplied to the sleeve.
- it is necessary that it be held. against rotation about the axis of the sleeve but this is aided by the slow rotation of the sleeve and thetapering of the thickness of the sleeve, the tapering starting in the wind ing zone of the material 63.
- the tube formed of the wrapped material 63 passes from the end of the sleeve 40, it is engaged with the coils of the wire 6i, which are also initially held against means for forming a continuous metallic spiral on said mandrel, a nut rotatable about said mandrel for advancing said spiral on saidmandrel, a rotatable threaded shaft for advancing the spiral from said mandrel, a tubular sleeve for I drel for advancing said spiral on said mandrel, a
- the pitch of the groove of the sleeve 43 which engages the wire coils determines the final spacing of these coils and this pitch may difler materially from the. pitch of the grooves of the nut l4 and shaft 38.
- the spool 58 is rotated in synchronism with and in the same direction as the shaft 38.
- the wire or cord ill from the spool 58 is passed over a guide 1b carried by the support 51 so a to retain the wire ii in position with respect to the corrugating groove in the sleeve 43 so that, once having been placed in properwrapping position in the groove it remains in the groove thereafter.
- the tubing 'after having the binding wire or cord applied thereto passes between guide and supporting rolls comprising a plurality of rolls 64 radially disposed with respect to the completed tubing and radially adjustable in a suitable frame 85 carried by an upper transverse frame member l3. From the rolls 64 the tubing passes to takeuprolls comprising spaced rolls 68 and, each having a plurality of grooves for receiving the tubing and over which the tubing is successively passed.
- the rolls 66 and 61 are supported on shafts 68 and 89, respectively, journalled in bearings carried by the upper and lower-longitudinal frame members, respectively.
- a sprocket 10 which is driven from the drive shaft 20 by means of the bevel gears l2, 13. reduction gearing l5, sprocket l4 and chain II. From the take-up rolls the tubing passes to suitable reels or other types of holders upon which it is rolled in desired lengths for shipment.
- a tubular sleeve for holding the coils of the spiral in the groove of said shaft and means for rotating said sleeve slowly oppositely tosaid shaft.
- a fixed mandrel means for forming a continuous metallic piral on said mandrel, a nut rotatable about said mandrel for advancing said spiralon said mandrel, said nut ending short of an end of said mandrel and permitting engagement of the coils of the spiral at said end of said mandrel, and a rotatable threaded shaft for advancing the coils ofthe spiral from said mandrel.
- a fixed mandrel means for forming a continuous metallic spiral on said mandrel, .a nut rotatable about of the spiral at said end of said mandrel, a rotatable threaded shaft for advancing the coil:
- a rotatable threaded shaft for advancing the coils of a continuous metallic spiral
- a rotatable sleeve enclosing said shaft and holding the spiral coils in the thread of said shaft, said sleeve having its exterior diameter decrease gradually toward the end away from said mandrel, and means for winding covering material for the spiral about said sleeve, said covering material being shifted along said sleeve and engaged with said spiral.
- a rotatable threaded shaft for advancing the coils of a continuous metallic spiral, a, sleeve enclosing said shaft and holding the coils of the spiral in the shaft thread, said sleeve being arranged to rotate oppositely to said shaft, and means for winding strip material about said sleeve to form pressure to the coils of the spiral.
- Such means comprises a bar or member 8
- is angularly shaped at its central portion to fit about the spiral on the mandrel 22 between the adjacent ends of the sleeve 40 and the nut i4.
- Spaced openings are provided in the member 0i to receive bolts 82 which also engage in spaced I openings in an angularly shaped member 88 forming with the member 8i a substantially rectangular opening receiving the mandrel and the coils of the spiral. Springs 86 confined between 1. In a tube forming machine, a fixedmandrel,
- a fixed man-- drel a spool for supplying continuous metallic retaining the coils of the spiral engaged with the shaft thread.
- a rotatable threaded shaft for advancing a continuous spiral spring
- a rotatable tubular sleeve en aging the coils of said spring on said threaded shaft
- a fixed mandrel for supplying continuous metallic material rotatable on said mandrel, means for forming a continuous spiral spring of said -rnaterial on said mandrel, a nut rotatable about said mandrel for advancing said spring on said mandrel and means supporting an end of said mandrel adjacent said spool, said means being removable to permit removal and replacement of said spool.
- a tube making machine a fixed mandrel, a spool for supplying continuous metallic material rotatable on said mandrel adjacent an end thereof, means for forming a continuous spiral spring of said material on said mandrel, a nut rotatable about said mandrel for advancing said spring on said mandrel, a threaded shaft for advancing said spring from said mandrel, said shaft being journalled in said mandrel, means supporting the mandrel end adjacent said spool and driving means for said threaded shaft comprising cooperating means on said shaft and said supporting means, said supporting means being removable to permit removal and replacement of said spool.
- a fixed man-' drel a spool for supplying continuous metallic material rotatable on said mandrel adjacent an end thereof, means for forming a continuous spiral spring of said material on said mandrel, a nut rotatable about said mandrel for advancing said spring on said mandrel, a threaded shaft for advancing said spring from said mandrel, said shaft being journalled in said mandrel, means engaging said mandrel adjacent said spool and holding said mandrel in fixed position and.
- drivlng means for said threaded shaft comprising cooperating gearing mounted on said shaft and said mandrel engaging means, said mandrel engaging means being removable to permit replacement of said spool.
- a fixed mandrel means rotatable about said mandrel for forming a continuous metallic spiral on said mandrel, a rotatable threaded shaft for advancing the spiral from said mandrel, a tubular sleeve for holding the coils of the spiral in the "groove of said shaft and means for varying the frictional resistance of said spiral to movement on said mandrel.
- .drel means rotatable about said mandrel for forming a continuous metallic spiral on said mandrel, a nut rotatable about said mandrel for advancing said spiral on said mandrel, said nut ending short of an end of said mandrel and permitting engagement of the coils of the spiral at said end of said mandrel, a rotatable threaded shaft for advancing the coils of the spiral from said mandrel, a tubular sleeve engaging the coils of the spiral and said mandrel and shaft and means carried by said sleeve and engaging coils on said mandrel beyond said nut for varying the frictional resistance of said coils to movement on said mandrel.
- a fixed mandrel means for forming a continuous metallic spiral on said mandrel, a nut rotatable about said mandrel for advancing said spiral on said mandrel, a rotatable threaded shaft for advancing the spiral from said mandrel, means for holding the coils of the spiral in the groove of said shaft and means for setting the coils of said spiral to a desired pitch.
- a fixed mandrel means for forming a continuous metallic spiral on said mandrel, a nut rotatable about said mandrel for advancing said spiral on said mandrel, a. rotatable threaded shaft for advancing the spiral from said mandrel, means for holding the coils of the spiral in the groove of said shaft and means detachably secured to said shaft for setting the coils of said spiral to a desired pitch.
- a fixed mandrel means for forming a continuous metallic spiral on said mandrel, a nut rotatable about saidmandrel for advancing said spiral on said mandrel, a rotatable threaded shaft for advancing the spiral from said mandrel, means for holding the coils of the spiral in the groove of said shaft and threaded means detachably securedto said shaft to rotate therewith for setting the coils of said spiral to a desired pitch.
- rotatable means for advancing tubular material comprising a 13.
- a fixed manmetallic piral and a covering thereon 'means driven by said advancing means for setting the pitch of said metallic spiral and means rotatable synchronously with said pitch setting means for wrapping a binding means about said tubular material at said pitch setting means and in a constant relation with respect to said pitch set ting means.
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Description
Dec. 26, 1944. A. E. CHERNACK MACHINE FOR MAKING TUBULAR STRUCTURES Filed June 3, 1942 4 Sheets Sheet l I .Ezuerziar C N R E H C E E B A g c Q ['F Jaw/liar Q & \N ABEL E.CHERN1ACK w. +l
Dec. 26, 1944. A. E. CHERNACK 2,366,087
' MACHINE FOR MAKING TUBULAR STRUCTURES Filed June 5, 1942 4 Sheets-Sheet '2 Fig.2..
Deg. 26, 1944. A. E. CHERNACK MACHINE FOR MAKING TUBULAR STRUCTURES Filed June 3, 1942 4 Sheets-Sheet 3 K C M r all 7w m n H e C NR mm w E m Aw I L m E n m B w\\ m a A i m m\m m 0 mm v vn w Nu haw /m& P m NNN 1944- 'AJE. CHERNACK ,3 8
MACHINE FOR MAKING TUBULAR STRUCTURES Filed June 3, 1942 4 Sheets-Sheet ABEL. E. CHERNACK y fill? aZ-tarneys Patented Dec. 26, 1944 MACHINE Foa MAKING TUBULAR 1 STRUCTURES v Abel E. Chernack, Elmwood, Conn. Application June 3, 1942, Serial No. 445,600
1 Claims. (Cl. 154-6) This invention relates to machines for making tubular structures and more particularly to a machine for forming tubing comprising an inner spiral supporting member and a covering member preferably wrapped about the supporting member and it is an object of this invention to provide a machine of the class described of improved construction and by which all steps of making such a tubular structure may be performed so as to produce a continuous tubular structure. It is also an object of this invention to provide a machine of the class described of. simple and efllcient construction and which may be easily operated and maintained.
In the drawings in which a machine of a preferred construction is shown for the purpose of illustration,
, Figure 1 is a top plan view of a tube forming machine constructed in accordance with this invention;
Figure 2 is a partial view in side elevation of the machine shown in Figure 1, some parts being broken away to show other parts more clearly;
Figure 3 is apartial view, partly in vertical section of a machine such as is shown in Fi ures 1 and 2, the view being taken on the longitudinal axis of the machine and showing a section of a machine for making a tube of relatively larger diameter than the machines of Figuresl and 2;
Figure 4 is a partial vertical sectional view drawn toa larger scale showing. parts of the machine adjacent to the parts shown in Figure 3 and forming acontinuation of the showing of Figure 3;
Figure 5 is a fragmentary view in elevation showing the driving mechanism at the left end of the machine as shown in Figures 1 and 2;
Figure 6 is a view in elevation of the means W supporting the gearing shown in Figure 5, shown detached from the machine and stripped of the Bearing;
v Figure 7 is a fragmentary vertical sectional view taken as on line 1-1 of Figure 3 and showing..,in side elevation the means for applying an of means 01. modified construction for applying pressure to the coils of the spiral; and
Figure 11 is a sectional view taken as on line il-ll of Fig. and showing on elevation the means for applying pressure to the coils of the spiral.
In the drawings a machine in accordance with this invention is shown as comprising a suitable frame having spaced vertical supporting memhere l, la, 2, 2a, 3, 3a, 4 and 4a joined "by upper longitudinal members 5, 6, lower longitudinal members I, 8 and upper and lower transverse members. The upper longitudinal members 5, 6 are cut away between the. vertical supporting members 20, la, and 2, 3, respectively. The upper longitudinal members 5.6 are joined at the vertical supporting members 2, 2a, by an irregularly shaped plate Ill which serves to support a journal box or bearing l2. Rotatably mounted in the bearing I2 is a tubular nut orbox I having an internal spiral groove i5 extending from a tangentially arranged leading-in passage ii at one end of the nut It to the opposite end of the nut. A sprocket l1 fixed on an end of the nut i4 and connected by a chain l8 to a corresponding sprocket fixed on a drive shaft 20 serves to drive the nut it. The drive shaftill is journalied in bearings mounted on the lower transverse members of the frame and has. at one end, the usual fast and loose drive pulleys 2| for driving the shaft 20 from a suitable source of power.
Closely fitting the cylindrical opening of the nut II is a mandrel 22 which projects at both ends of the nut ll. As shown in Figure 3, the mandrel projects but a short distance to the right of the nut ll while it projects to the left sufliciently to serve as a support for the spool 24 of wire or other metallic strip material of and longitudinal movement. The bracket 26 is adjustable frictional resistance to the movement oi the coilslongitudinally of the mandrel;
Figure 8 is an end view showing the arrangement of the tube supporting and guiding rolls shown in Figures 1, 2 and 4; Figure 9 is a substantially. diagrammatic view in side elevation of the take-up rolls for drawing the finished tubing from the machine;
Figure 10 is a fragmentary plan view showing the application to the machine of Figs. 1 and 2 split at its lower end and'the separated portions may be drawn together by means of a bolt 21 so as to permit of the bracket being secured on a stud 28 mounted in the upper transverse member 8. The upper end of the bracket 26 is formed of two portions. one portion 26a being integral with the remainder of the bracket and having a bolt 29 pivotally mounted at its upper end while the other portion 26b is pivotally connected at one end to the main portion of the bracket 26, as at 28c, and is forked at its other 43 on theprojecting end to receive the bolt 29. The bracket portions 26a and 26b fit into the groove in the end of the mandrel 22 and, when drawn together by the winged nut 29a on the bolt 29. hold the mandrel in fixed position.
Mounted in the bracket 26 is a stud 39 on which is journalled a gear 32 driven by'a gear 34 and driving a gear 36. The gear 34 is journalled on the stud 28. and is attached to a sprocket 33 driven by a chain 35 from a corresponding sprocket 31 fixed on the drive shaft 28. The gear 36 is fixed on the reduced end 38a of a threaded shaft 38.- The threaded shaft abuts an end of the mandrel 22 and has its reduced end portion 38a extending through the mandrel 22 to receive the gear 36. The gear 36 is of less diameter than the adjacent end of the mandrel 22 so that when the bracket 36 is released from the mandrel 22 and rotated slightly on the stud 28, carrying the gear 32 from the gear 36, the spool 24 can be removed from the mandrel without necessitating removal of the gear'36 from the shaft 38, thus providing for the replacement of empty spools with a minimum of dismantling of the machine. The main body portion of the threaded shaft 38 is rotatably mounted in a sleeve 40. The sleeve 40 which abuts the end of the nut I4, overlapping the adjacent end of the mandrel 22, extends to the end'of the main body portion of the shaft 38 .and tapers gradually in, thickness from a point intermediate its length. The sleeve 48 is mounted to rotate with a bracket support 42 journalled in a bearing 44 mounted on the plate Ill. The bracket support 42 is rotated by means of a gear 46 fixed to the bracket support 42 and driven by a pinion 41. The pinion 41 is fixed on a shaft journalled in a bearing 48 mounted on the plate I and this shaft has fixed thereon a sprocket 49 driven by, a chain 59 from a vsuitable sprocket fixed on the drive shaft 20. Adjustably mounted rotatably mounted on a support 51 which has a tubular journal 51a permitting the passage of the tube and supported in a bearing 58 carried by the upper transverse member II of the frame. The support 51 is rotated by means of a sprocket 59 fixed on the journal 51a and connected by a chain 60 to a corresponding sprocket fixed on the drive shaft 28.
When the machine is in operation wire 6| or other suitable strip metallic material passes from the spool 24 around a guide roller 62 carried by an arm I4a mounted on the nut I4. From the guide roller the wire 6| passes through the leading-in passage I6 to the spiral groove in the nut I4, the spiral groove forming a passage be tween the nut I4 'and the mandrel 22, and the rotation of the nut I4 while the mandrel 22 is held stationary causing the coils of the wire to be advanced along the mandrel 22. To prevent the full load of starting rotation of the spool 24 being carried by the wire 6| and the tension on the wire thereby increased, the nut I4 is provided with an arm |4b carrying a, pawl I40 adapted to engage ratchet teeth 24a in a, side of the spool 24 so that the spool 24 can not rotate at a less rate than the nut I4, but can be rotated faster.
The wire coils will be advanced uniformly along the mandrel 22 by the nut I4 until the end on an extension 42a of the bracket support 42,
arethe bracket arms 52 having, at one end, an axle supporting a roll 54 of suitable wrapping material and, at the other end, a second roll or a counterweight 55 of suitable proportions. A screw 53 passing through a slot in the arms 52 and engaging in a threaded opening in the extension 42a serves to retain the arms 52 in adjusted position. The arms 52 may be jointed, as at 52a, to provide for adjustment of the roll 54 in each of two directions.
The main body portion of the threaded shaft 38 is of uniform diameter for the full length of the sleeve 40 and has a cylindrical portion-38b of reduced diameter projecting beyond the sleeve 40. A collar 39 fastened to the projecting portion 38b by apin 4| secures an externally threaded sleeve portion 38b. A dowel engaging the adjacent ends of the main body portion of the shaft 38 and the sleeve 43 secures the sleeve 43 in a predetermined position with respect to the shaft 38 and prevents relative rotation of the shaft and sleeve. The sleeve 43 is formed with a plurality of external spiral grooves, one of which forms a continuation of the groove of the shaft 38 and receives the wire or metallic strip forming the interior spiral of the tube. The other of the grooves is deeper than the first groove and provides space to permit of corrugating the tube by means of a suitable wire or cord 5I which is wrapped about the tube between the coils of the inner metallic spiral and serves to corrugate the tube and secure the wrappings in position.
The wire or cord 5| is supplied froma spool 56 of the nut I4 is reached whereupon the advance of the coils is slowed as theirfurther movement along the mandrel is dependent upon the delivery of additional coils of the wire from the nut I4. This delivery of additional coils from the nut I 4 gradually forces the coils forward on the mandrel 22 to be engaged in the grooveof the threaded shaft 38. In order to increase the friction on the coils or spring on the fixed mandrel 22 to assure the formation of the spring or spiral the sleeve 40,
where it overlaps the adjacent projecting end of the mandrel 22 where the coils of the spiral are closely grouped, is provided with a collar or ring I9 shrunk or otherwise secured on the sleeve 49 at its end. The ring I9 and the sleeve 49 are provided with alined openings so positioned that a plunger 23 mounted in the openings, bears against the closely grouped coils on the mandrel.
A lever 25 pivotally connected at one end, as at 25a, to the ring I9 outer end of the plunger 23.
at its other end on the Intermediate its ends the lever 25 is provided with an opening to receive freely a bolt 3| having one end engaged in a threaded opening in the ring I9. The other bears end of bolt 3| is threaded to adjustably receive a nut 3|a which serves to adjustably stress a sprin 3 lb confined between the nut and the lever 25 and thus adjustably control the pressure exerted by the plunger 23 on the coils closely grouped on'the mandrel 22. The threaded shaft 38 is operated at the same speed of rotation as the nut I4 ,so that the coils are removed from the end of the mandrel 22 by the shaft 38 as fast as they are supplied by the nut I4. The coils in the groove of the shaft 38 tend to unwind and expand, particularly during an initial starting operation of the machine, causing the coils to drag heavily on the sleeve 49. By rotating the sleeve 40 slowly in the direction opposite to the rotation of the shaft 38 a twisting or tightening effect is had upon the coils, the friction of the coils upon the sleeve greatly reduced and the movement of the coils along the sleeve 40 by the threaded shaft 38 greatly facilitated. v
Rotating with the sleeve 48 is the spool 54 of any suitable wrapping material 63 which 'is wrapped about the sleeve 40, the number of layers provided being varied as required by varying the width of the wrapping material, speed of rotation about the sleeve and the angle at which the material issupplied to the sleeve. In starting the wrapping of the material 63, it is necessary that it be held. against rotation about the axis of the sleeve but this is aided by the slow rotation of the sleeve and thetapering of the thickness of the sleeve, the tapering starting in the wind ing zone of the material 63. As the tube formed of the wrapped material 63 passes from the end of the sleeve 40, it is engaged with the coils of the wire 6i, which are also initially held against means for forming a continuous metallic spiral on said mandrel, a nut rotatable about said mandrel for advancing said spiral on saidmandrel, a rotatable threaded shaft for advancing the spiral from said mandrel, a tubular sleeve for I drel for advancing said spiral on said mandrel, a
rotation, and then pressed between the coils of the wire spiral by the'wrapping or binding wire 5 i The pitch of the groove of the sleeve 43 which engages the wire coils determines the final spacing of these coils and this pitch may difler materially from the. pitch of the grooves of the nut l4 and shaft 38. The spool 58 is rotated in synchronism with and in the same direction as the shaft 38. The wire or cord ill from the spool 58 is passed over a guide 1b carried by the support 51 so a to retain the wire ii in position with respect to the corrugating groove in the sleeve 43 so that, once having been placed in properwrapping position in the groove it remains in the groove thereafter.
The tubing, 'after having the binding wire or cord applied thereto passes between guide and supporting rolls comprising a plurality of rolls 64 radially disposed with respect to the completed tubing and radially adjustable in a suitable frame 85 carried by an upper transverse frame member l3. From the rolls 64 the tubing passes to takeuprolls comprising spaced rolls 68 and, each having a plurality of grooves for receiving the tubing and over which the tubing is successively passed. The rolls 66 and 61 are supported on shafts 68 and 89, respectively, journalled in bearings carried by the upper and lower-longitudinal frame members, respectively. The upper shaft 6! has keyed thereon a sprocket 10 which is driven from the drive shaft 20 by means of the bevel gears l2, 13. reduction gearing l5, sprocket l4 and chain II. From the take-up rolls the tubing passes to suitable reels or other types of holders upon which it is rolled in desired lengths for shipment.
While the spring pressed plunger 23 shown in Figs. 3 and 7 arranged to bear on the coils of the rotatable threaded shaft for advancing the spiral,
a tubular sleeve for holding the coils of the spiral in the groove of said shaft and means for rotating said sleeve slowly oppositely tosaid shaft.
3. In a tube forming machine, a fixed mandrel, means for forming a continuous metallic piral on said mandrel, a nut rotatable about said mandrel for advancing said spiralon said mandrel, said nut ending short of an end of said mandrel and permitting engagement of the coils of the spiral at said end of said mandrel, and a rotatable threaded shaft for advancing the coils ofthe spiral from said mandrel.
4. In a tube forming machine, a fixed mandrel, means for forming a continuous metallic spiral on said mandrel, .a nut rotatable about of the spiral at said end of said mandrel, a rotatable threaded shaft for advancing the coil:
of the spiral fromsaid mandrel and a sleeve rotatable oppositely to 'said threaded shaft and engaging the spiral on said mandrel and threaded shaft. I v
5. In a tube forming machine, -a rotatable threaded shaft for advancing the coils of a continuous metallic spiral, a rotatable sleeve enclosing said shaft and holding the spiral coils in the thread of said shaft, said sleeve having its exterior diameter decrease gradually toward the end away from said mandrel, and means for winding covering material for the spiral about said sleeve, said covering material being shifted along said sleeve and engaged with said spiral.
6. In a tube forming machine, a rotatable threaded shaft for advancing the coils of a continuous metallic spiral, a, sleeve enclosing said shaft and holding the coils of the spiral in the shaft thread, said sleeve being arranged to rotate oppositely to said shaft, and means for winding strip material about said sleeve to form pressure to the coils of the spiral. Such means comprises a bar or member 8| mounted on studs an carried'by the bearing 44. The member 8| is angularly shaped at its central portion to fit about the spiral on the mandrel 22 between the adjacent ends of the sleeve 40 and the nut i4. Spaced openings are provided in the member 0i to receive bolts 82 which also engage in spaced I openings in an angularly shaped member 88 forming with the member 8i a substantially rectangular opening receiving the mandrel and the coils of the spiral. Springs 86 confined between 1. In a tube forming machine, a fixedmandrel,
a covering for said spiral, said covering being shifted longitudinally of said sleeve synchronously with the coils of said spiral and engaged with said spiral.
7. In a tube forming machine, a fixed man-- drel, a spool for supplying continuous metallic retaining the coils of the spiral engaged with the shaft thread.
8.'Ina tube forming machine, a rotatable threaded shaft for advancing a continuous spiral spring, a rotatable tubular sleeve en aging the coils of said spring on said threaded shaft, means for wrapping covering material about said sleeve to form a covering for said spring and means engaging said covering with said spring.
9. In a tube forming machine, a fixed mandrel, a spool for supplying continuous metallic material rotatable on said mandrel, means for forming a continuous spiral spring of said -rnaterial on said mandrel, a nut rotatable about said mandrel for advancing said spring on said mandrel and means supporting an end of said mandrel adjacent said spool, said means being removable to permit removal and replacement of said spool. v
10.'In a tube making machine, a fixed mandrel, a spool for supplying continuous metallic material rotatable on said mandrel adjacent an end thereof, means for forming a continuous spiral spring of said material on said mandrel, a nut rotatable about said mandrel for advancing said spring on said mandrel, a threaded shaft for advancing said spring from said mandrel, said shaft being journalled in said mandrel, means supporting the mandrel end adjacent said spool and driving means for said threaded shaft comprising cooperating means on said shaft and said supporting means, said supporting means being removable to permit removal and replacement of said spool.
11. In a tube forming machine, a fixed man-' drel, a spool for supplying continuous metallic material rotatable on said mandrel adjacent an end thereof, means for forming a continuous spiral spring of said material on said mandrel, a nut rotatable about said mandrel for advancing said spring on said mandrel, a threaded shaft for advancing said spring from said mandrel, said shaft being journalled in said mandrel, means engaging said mandrel adjacent said spool and holding said mandrel in fixed position and. drivlng means for said threaded shaft comprising cooperating gearing mounted on said shaft and said mandrel engaging means, said mandrel engaging means being removable to permit replacement of said spool.
12. In a tube forming machine, a fixed mandrel, means rotatable about said mandrel for forming a continuous metallic spiral on said mandrel, a rotatable threaded shaft for advancing the spiral from said mandrel, a tubular sleeve for holding the coils of the spiral in the "groove of said shaft and means for varying the frictional resistance of said spiral to movement on said mandrel.
.drel, means rotatable about said mandrel for forming a continuous metallic spiral on said mandrel, a nut rotatable about said mandrel for advancing said spiral on said mandrel, said nut ending short of an end of said mandrel and permitting engagement of the coils of the spiral at said end of said mandrel, a rotatable threaded shaft for advancing the coils of the spiral from said mandrel, a tubular sleeve engaging the coils of the spiral and said mandrel and shaft and means carried by said sleeve and engaging coils on said mandrel beyond said nut for varying the frictional resistance of said coils to movement on said mandrel.
14. In a tub forming machine, a fixed mandrel, means for forming a continuous metallic spiral on said mandrel, a nut rotatable about said mandrel for advancing said spiral on said mandrel, a rotatable threaded shaft for advancing the spiral from said mandrel, means for holding the coils of the spiral in the groove of said shaft and means for setting the coils of said spiral to a desired pitch.
15. In a tube forming machine, a fixed mandrel, means for forming a continuous metallic spiral on said mandrel, a nut rotatable about said mandrel for advancing said spiral on said mandrel, a. rotatable threaded shaft for advancing the spiral from said mandrel, means for holding the coils of the spiral in the groove of said shaft and means detachably secured to said shaft for setting the coils of said spiral to a desired pitch.
16. In a tubeforming machine, a fixed mandrel, means for forming a continuous metallic spiral on said mandrel, a nut rotatable about saidmandrel for advancing said spiral on said mandrel, a rotatable threaded shaft for advancing the spiral from said mandrel, means for holding the coils of the spiral in the groove of said shaft and threaded means detachably securedto said shaft to rotate therewith for setting the coils of said spiral to a desired pitch.
17. In a tube forming machine, rotatable means for advancing tubular material comprising a 13. In a tube forming machine, a fixed manmetallic piral and a covering thereon, 'means driven by said advancing means for setting the pitch of said metallic spiral and means rotatable synchronously with said pitch setting means for wrapping a binding means about said tubular material at said pitch setting means and in a constant relation with respect to said pitch set ting means.
. ABEL E. CHERNACK.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US445600A US2366087A (en) | 1942-06-03 | 1942-06-03 | Machine for making tubular structures |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US445600A US2366087A (en) | 1942-06-03 | 1942-06-03 | Machine for making tubular structures |
Publications (1)
Publication Number | Publication Date |
---|---|
US2366087A true US2366087A (en) | 1944-12-26 |
Family
ID=23769534
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US445600A Expired - Lifetime US2366087A (en) | 1942-06-03 | 1942-06-03 | Machine for making tubular structures |
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US (1) | US2366087A (en) |
Cited By (11)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2486387A (en) * | 1944-05-30 | 1949-11-01 | American Ventilating Hose Co | Hose |
US2489503A (en) * | 1948-10-07 | 1949-11-29 | Gen Motors Corp | Machine for making tubing |
US2501644A (en) * | 1946-01-26 | 1950-03-21 | Gen Tire & Rubber Co | Method of building steel cable tire ply bands |
US2551631A (en) * | 1947-11-22 | 1951-05-08 | Hoover Co | Method of making suction cleaner hose |
US2705041A (en) * | 1949-11-19 | 1955-03-29 | Eagle Picher Co | Apparatus for manufacture of reinforced flexible tubing |
US2730762A (en) * | 1953-04-21 | 1956-01-17 | American Viscose Corp | Apparatus for the continuous fabrication of reinforced tubing |
US2800683A (en) * | 1953-11-24 | 1957-07-30 | Krauss Maffei Ag Fa | Apparatus for manufacturing reinforced members |
US2832096A (en) * | 1953-09-21 | 1958-04-29 | Vance M Kramer | Apparatus for making corrugated rubber tubing and the like |
US4294064A (en) * | 1979-01-01 | 1981-10-13 | Felten & Guilleaume Carlswerk | Method of and a device for balancing a changing load of a strip roll orbiting about an axis in a strip winding machine |
US20030056559A1 (en) * | 2001-09-22 | 2003-03-27 | Nexans | Method for producing longitudinally welded helically corrugated metal tubing |
US20160250822A1 (en) * | 2015-02-26 | 2016-09-01 | AHN Chem Co., LTD | Radiant insulation protector manufacturing apparatus and radiant insulation protector manufactured using same |
-
1942
- 1942-06-03 US US445600A patent/US2366087A/en not_active Expired - Lifetime
Cited By (13)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2486387A (en) * | 1944-05-30 | 1949-11-01 | American Ventilating Hose Co | Hose |
US2501644A (en) * | 1946-01-26 | 1950-03-21 | Gen Tire & Rubber Co | Method of building steel cable tire ply bands |
US2551631A (en) * | 1947-11-22 | 1951-05-08 | Hoover Co | Method of making suction cleaner hose |
US2489503A (en) * | 1948-10-07 | 1949-11-29 | Gen Motors Corp | Machine for making tubing |
US2705041A (en) * | 1949-11-19 | 1955-03-29 | Eagle Picher Co | Apparatus for manufacture of reinforced flexible tubing |
US2730762A (en) * | 1953-04-21 | 1956-01-17 | American Viscose Corp | Apparatus for the continuous fabrication of reinforced tubing |
US2832096A (en) * | 1953-09-21 | 1958-04-29 | Vance M Kramer | Apparatus for making corrugated rubber tubing and the like |
US2800683A (en) * | 1953-11-24 | 1957-07-30 | Krauss Maffei Ag Fa | Apparatus for manufacturing reinforced members |
US4294064A (en) * | 1979-01-01 | 1981-10-13 | Felten & Guilleaume Carlswerk | Method of and a device for balancing a changing load of a strip roll orbiting about an axis in a strip winding machine |
US20030056559A1 (en) * | 2001-09-22 | 2003-03-27 | Nexans | Method for producing longitudinally welded helically corrugated metal tubing |
US6789318B2 (en) * | 2001-09-22 | 2004-09-14 | Nexans | Method for producing longitudinally welded helically corrugated metal tubing |
US20160250822A1 (en) * | 2015-02-26 | 2016-09-01 | AHN Chem Co., LTD | Radiant insulation protector manufacturing apparatus and radiant insulation protector manufactured using same |
US9776375B2 (en) * | 2015-02-26 | 2017-10-03 | AHN Chem Co., LTD | Radiant insulation protector manufacturing apparatus and radiant insulation protector manufactured using same |
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