US3593509A - Apparatus and a method for stranding a twisted unit of a cable - Google Patents

Apparatus and a method for stranding a twisted unit of a cable Download PDF

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Publication number: US3593509A
Authority: US; United States
Prior art keywords: twisted; point; twisting; stranding; twisted unit
Prior art date: 1968-05-21
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

Application number

US825647A

Other languages

English (en)

Inventor

Wolfgang Feese

Heinz Oberender

Heinz Badura

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Siemens AG

Siemens Corp

Original Assignee

Siemens Corp

Priority date (The priority date 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 date listed.)

1968-05-21

Filing date

1969-05-19

Publication date

1971-07-20

1969-05-19 Application filed by Siemens Corp filed Critical Siemens Corp

1971-07-20 Application granted granted Critical

1971-07-20 Publication of US3593509A publication Critical patent/US3593509A/en

1988-07-20 Anticipated expiration legal-status Critical

Status Expired - Lifetime legal-status Critical Current

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Classifications

- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01B—CABLES; CONDUCTORS; INSULATORS; SELECTION OF MATERIALS FOR THEIR CONDUCTIVE, INSULATING OR DIELECTRIC PROPERTIES
- H01B13/00—Apparatus or processes specially adapted for manufacturing conductors or cables
- H01B13/02—Stranding-up
- H01B13/0235—Stranding-up by a twisting device situated between a pay-off device and a take-up device
- H01B13/0264—Stranding-up by a twisting device situated between a pay-off device and a take-up device being rollers, pulleys, drums or belts
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01B—CABLES; CONDUCTORS; INSULATORS; SELECTION OF MATERIALS FOR THEIR CONDUCTIVE, INSULATING OR DIELECTRIC PROPERTIES
- H01B13/00—Apparatus or processes specially adapted for manufacturing conductors or cables
- H01B13/02—Stranding-up
- H01B13/0235—Stranding-up by a twisting device situated between a pay-off device and a take-up device

Definitions

the stranding elements which remain united in the stranding or twisted unit are led in a stretched twisted condition to a twisting device which twists the twisted unit in sections, each of a multiple of stranding strokes.
the twisting device is positioned closer to the takeup point than to the payout point of the twisted unit.
a longitudinal section of the twisted unit has a minimum length equal to the distance between the takeup point and the twisting device and a maximum length equal to three times the distance between the twisting device and the payout point.
the present invention relates to apparatus and a method for stranding a twisted unit of a cable. More particularly, the invention relates to apparatus and a method for stranding a twisted unit of a cable in different directions of stranding for individual lengths.
stranding or twisting operations which have previously been undertaken separately. These operations are, for example, stranding or twisting of basic units and main units into one work operation in order to enhance efficiency. For this purpose, stranding processes are required to assist the stranding of the twisted units.
Each twisted unit comprises a plurality of twisted elements. The twisted units are stranded or twisted alternately with a left-hand lay or S-twist and a right-hand lay or Z-twist in continuous lengths.
All stranding or twisting of this type known as oscillated twisting, and lately known as S2 twisting, has the advantage that the elements to be twisted may be paid out from stationary supply sources and that further processing of the twisted unit, which is formed by twisting such elements, may be undertaken immediately after twisting during the same work operation utilizing the S2 twisting process.
a device described in German Pat. No. DAS 1,197,144 for stranding telephone cables operates without the aforedescribed cradles.
the wire pairs pulled from stationary payout reels in groups are led through a single oscillating disc each.
the oscillating discs swing back and forth or oscillate in alternating sequence thereby turning alternately in one direction and then in the other.
the oscillating twisting or stranding discs may not, however, be turned by more than :l80. If the oscillating discs were turned by more than 180, the wire groups would twist too much in front of said discs and the pretwisted elements pulled against the oscillating discs when they are moved from the payoff reels would break off or be damaged.
the max imum phase angle of twist thus remains small. Furthermore, the twists attained have proven to be insufficient for electrical decoupling of the twisted elements of telephone cables.
the principal object of the present invention is to provide a new and improved process and apparatus for stranding a twisted unit of a cable in different directions of stranding for individual lengths.
An object of the present invention is to provide a process and apparatus for stranding a twisted unit of a cable in different directions of stranding with rapidity, efficiency, effectiveness and reliability.
An object of the present invention is to provide a process and apparatus for stranding a twisted unit of a cable in different directions of stranding, which process and apparatus overcome the disadvantages of known processes and apparatus of similar type.
An object of the present invention is to provide apparatus of simple structure for stranding a twisted unit of a cable in different directions of stranding.
a twisted unit of a cable such as, for example, a communication cable comprising a plurality of elements
the elements of the twisted unit are led to a stationary payout point at which the twisted unit is formed from such elements.
the twisted unit is then led from the payout point to a twisting device in a switched rotatable condition perpendicular to the axis of the twisted unit.
the twisting device grasps the twisted unit and turns said twisted unit by a multiple of twists sectionwise between the payout point and a stationary takeup point at which a different twist of the twisted unit is provided sectionwise.
the distance between the takeup point and the point at which the twisting device grasps the twisted unit is smaller than the distance between the point at which the twisting device grasps the twisted unit and the payout point.
a single length section'having the same twist direction of the twisted unit has a minimum length equal to the distance between the takeup point and the point at which the twisting device grasps the twisted unit and a maximum length equal to three times the distance between the point at which the twisting device grasps the twisted unit and the payout point.
the process and apparatus of the present invention insures that each length section of the twisted unit having a different direction of twisting is provided with a sufficient number of twists, whereas simultaneously the periodic variation in the direction of twisting and/or the speed of the twisting device is undertaken so rapidly that any significant decrease in the turning of the length section of the twisted unit passing through the twisting device, resulting from the operation of the twisting device because of the twisted unit approaching too close to the buildup condition, is avoided.
the twisted unit is twisted between the payout point and the point at which the twisting device grasps the twisted unit. Only a portion of the twisted unit may slip through the twisting device during the process.
the twisting of the twisted unit increases continuously between the payout point and the point at which the twisting device grasps the twisted unit.
the speed of the twisting device remains constant, an equilibrium condition occurs between the twisting of the twisted unit led to the twisting device and the twist per length section provided by the twisting device.
the torsion of the part of the twisted unit in front of the twisting device would attain an end value.
the twisting of the part of the twisted unit in the pulloff direction behind the twisting device would be equal to zero.
the apparatus and method of the present invention are based upon the conception that the end value is provided by the uniformity of twisting provided per length section by the twisting device on one hand, and the twisting of the twisted unit led to the twisting device on the other hand.
the invention is also based on the conception that up to the instant the end value is reached, the length section of the twisted unit passing through the twisting device is provided with a twist in the same direction. Before the end value is reached, a new end value is provided by changing the direction of rotation and/or speed of the twisting device. Twisting of the twisted unit is then continued to a later instant before the new end value is reached.
the distance between the takeup point and the point of engagement of the twisting device with the twisted unit is made essentially shorter than the distance between the point of engagement of the twisting device with the twisted unit and the payout point. This results in an extraordinarily high degree of efficiency, so that a relatively small speed of the twisting device is sufficient to guarantee adequate twisting of the twisted unit led to the takeup point.
the relation between the distance between the takeup point and the point of engagement of the twisting device with the twisted unit and the distance between the point of engagement of the twisting device with the twisted unit and the payout point is varied continuously or in stages during the twisting process.
apparatus for stranding a twisted unit of a cable in different directions of stranding for individual lengths comprises a plurality of cable elements.
a fixed payout point forms a twisted unit from the cable elements.
a twisting device engages the twisted unit in a nonpositive manner perpendicular to the axis of the twisted unit.
the twisted unit is led to the twisting device in stretched rotatable condition.
the twisting device rotates the twisted unit a number of twists between the payout point and the takeup point and provides a different direction of stranding of the twisted unitfor individual section lengths.
the twisting device engages the twisted unit at a point closer to the takeup point than to the payout point.
a section of the twisted unit having the same direction of stranding has a minimum length which is the length between the takeup point and the engagement point of the twisting device and a maximum length which is three times the length between the engagement point and the payout point.
the twisting device is positioned as close as possible to the takeup point.
the twisted unit is stranded at the takeup point and one of the speed and direction of rotation of the twisting device is regulated in accordance with the stranding of the takeup point during the passage through the twisting device of a section of the twisted unit having the same direction of stranding.
the regulation of the one of the speed and direction of rotation provides stranding which is as constant as possible over the entire section of the twisted unit having the same direction of stranding.
a stranding device is provided between the twisting device and the takeup point for stranding a plurality of twisted units.
the regulation of the one of the speed and direction of rotation provides resultant stranding of the stranding device of uniform size and length.
the speed of the twisting device is increased during the passage through the twisting device of a section of the twisted unit having the same direction of stranding.
the speed of the twisting device is varied during the passage through the twisting device of a section of the twisted unit having the same direction of stranding.
the twisting device rotates in a single direction during twisting of the twisted unit.
the twisting device rotates intermittently in a single direction during twisting of the twisted unit.
the twisting device is rotated after reaching a specific minimum during the stranding of the section of the twisted unit.
the twisting device is rotated and engages in a nonpositive manner a length of twisted unit perpendicular to the axis of the twisted unit preventing spreading thereof.
the length of engaged twisted unit is shorter than the length of twisted unit to be twisted in the direction of rotation of the twisting device.
the twisting device comprises spaced components on both sides of the twisted unit and the components contact the twisted unit with a pressure which does not hinder the passage of the twisted unit through the twisting device.
the twisting device functions as a lever relative to the axis of the twisted unit and transfers force to the twisted unit in the direction of rotation of the twisting device by deflection of the twisted unit.
the twisting device comprises three spaced rollers mounted for coplanar rotation with their axes positioned in a manner whereby the twisted unit passes in contact with each of the rollers in curvilinear fashion.
An additional twisting device between the payout point and the twisting device provides homogeneous stranding of the section of the twisted unit between the payout point and the twisting device.
the twisting device and the additional twisting device rotate in the same direction at increasing speeds relative to the advancing of the twisted unit.
a process for stranding a twisted unit of a cable in different directions of stranding for individual lengths comprises the steps of forming a twisted unit from a plurality of cable elements at a payout point and twisting the twisted unit in a nonpositive manner perpendicular to the axis of the twisted unit a number of twists at a point between the payout point and a takeup point and providing a different direction of stranding of the twisted unit for individual section lengths when the twisted unit is in stretched rotatable condition at a point closer to the takeup point than to the payout point.
a section of the twisted unit having the same direction of stranding has a minimum length which is the length between the takeup point and the twisting point and a maximum length which is three times the length between the twisting point and the payout point.
the distance between the takeup point and the twisting point is considerably smaller than the distance between the twisting point and the payout point.
the relation of the distance between the takeup point and the twisting point and the distance between the twisting point and the payout point is varied.
the process further comprises the step of stranding a plurality of twisted units, each twisted by twisting a correspond ing one of a plurality of twisted units.
Each of the twisted units is twisted at a varying one of speed and direction of rotation. The variation of twisting occurs at a time different from that of the others.
Each of the twisted units is twisted at a different one of speed and direction of rotation from that of the others.
Each of the twisted units is twisted at a twisted point a distance from a corresponding takeup point and a distance from a corresponding payout point which have a different relation to each other from the others.
FIG. 1 is a schematic diagram of an embodiment of the apparatus of the present invention for performing the process of the present invention
FIG. 2 is a graphical presentation of the stranding process of the present invention
FIG. 3 is a schematic diagram of another embodiment of the apparatus of the present invention.
FIG. 4 is a schematic diagram of another embodiment of the apparatus of the present invention.
FIG. 5 is a schematic diagram of an embodiment of a twisting device
FIG. 6 is a schematic diagram of another embodiment of a twisting device
FIG. 7 is a schematic diagram of another embodimentof a twisting device.
FIG. 8 is a top view of the twisting device of FIG. 7.
the basic unit of a communication cable having unit-type design is assumed to be the twisted unit.
the twisted unit comprises elements or strands 2.
a plurality of payout stands or sources provide the elements or strands 2.
five strands 2 are led to a payout point E.
a nipple 9 at the payout point E combines the five elements 2 into a basic twisted unit 1.
the twisted or basic unit 1 is led to a twisting device 4 in a stretched rotatable or twisted condition.
the twisting device 4 engages the twisted unit 1 perpendicularly to the axis of said twisted unit in a nonpositive manner.
the twisted unit 1 is then led in the direction of the arrow to the takeup point A where it is wound on a take up reel 5.
the takeup point A is determined so that it fixes the different twisting directions of the twisted unit 1 sectionwise.
the distance bbetween the takeup point A and the point of engagement of the twisting device 4 with the twisted unit 1 is smaller than the distance a between the point of engagement of twisting device 4 with the twisted unit and the payout point E.
Twisted units of cable such as, for example, the twisted unit I
Twisted units of cable are generally not ideally elastic as far as torsion is concerned.
twisting of the part of the twisted unit 1 between the payout point E and the twisting device 4 is nonhomogeneous.
This nonhomogeneous condition is dependent upon the makeup and, particularly, on the diameter of the twisted unit 1.
the twisted or basic unit 1 comprises five elements or strands, as assumed for the illustration of the present invention, nonhomogeneous conditions have occurred when the distance or length a is greater than 5 meters.
the twisting of the twisted unit 1 at the take up point A is not constant, in accordance with the present invention. This is explained in FIG. 2 by indicating the length I as the abscissa and indicating the twisting as the ordinate.
the curve of FIG. 2 is for a wire pair twisted in accordance with the SZ twisting process, utilizing the apparatus of FIG. 1.
the twisting within a length L is n the same direction and increases initially to its maximum value and then decreases gradually to its minimum value.
the direction of rotation of the twisting device 4 is therefore reversed in sufficient time before reaching the buildup state, which buildup state means a twisting value 0 equal to zero.
FIG. 3 illustrates apparatus for twisting a common cable.
the strands or elements 2 and 2' are led from stationary supply stands or sources (not shown in FIG. 3) to corresponding nipples 9, 9, and so on, in groups of five strands.
Each of the nipples 9, 9, and so on forms a twisted or basic unit 1 which is then wound by an open holding helix with the assistance of a spinner 8, 8 and so on.
the twisted units 1, l, and so on are led to a stranding point via guide pulleys 2], 21, and so on, and twisting devices 4, 4, and so on.
a nipple is positioned at the stranding point.
the nipple 10 combines the twisted units 1, I, and so on, into a main unit 7.
the main unit 7 is wound on the takeup reel 5' in a stranding yoke 6.
the twisted units I are stranded or twisted between the nipples 9, 9', and so on, where they are formed from the elements or strands 2, and the nipple 10 which strands or twists the twisted units 1, 1, and so on, into the main unit 7, by periodic variation of the speed and/or direction of rotation of the twisting devices 4, 4, and so on.
the twisting devices 4, 4', and so on are positioned as close as possible to the nipple 10.
the twisted units 1, l, and so on are led to the nipple l0with a specific type of stranding.
the influence of the twisting devices 4, 4, and so on, on the additional stranding or twisting of said twisted units is eliminated by the stranding of said twisted units into the main unit 7.
twisting device twists the wire groups comprising wire pairs before the wire pairs are led to the nipple which twists them, in the same work operation.
the speed and/or direction of rotation of the twisting device of each of the parallel work operation apparatus may be varied or changed at a time different from that of the others. This insures electrical decoupling of the twisted units strained together. This may also be achieved by operating the twisting devices of the parallel work operation apparatus at speeds and/0r directions of rotation which are different from each other.
the distance between the takeup point of the twisted unit and the point of engagement of the twisting device with the twisted unit and/or the distance between the point of engagement of the twisting device with the twisted unit and the payout point of the twisted unit may be selected differently.
stranding in the individual lengths L of a twisted unit is not constant in the process of the present invention. It is, however, often desired that stranding or twisting be as constant as possible within the sequential length of a twisted unit.
the speed or, if necessary, the direction of rotation, of the twisting device may be regulated during the time in which a length of the twisted unit, in completed condition having the same direction of lay in accordance with the stranding, is provided at the takeup point.
the speed of the twisting device may be increased continuously, for example, or in stages, while a length of a twisted unit having the same stranding direction passes through said twisting device. It is, however, also possible to vary the speed of advance while a length of the twisted unit having the same stranding direction is passing through the twisting device.
the switching or energization of the twisting device may be delayed after the periodic variation in the speed and/or direction of rotation of said twisting device has commenced, so that the stranding or twisting which has accumulated in front of said twisting device in the direction of advance of the twisted unit may gradually diminish.
the regulation of the speed and, if necessary, the direction of rotation of the twisting device may be provided in a manner whereby during the period that a length of the twisted unit having the same direction of stranding is passing through the twisting device, stranding is as constant as possible over said entire length of the twisted unit. It is also possible to provide speed or direction of rotation regulation in a manner whereby the resultant combined stranded units such as, for example, the main units, each of which comprises a plurality of twisted units, are as equal to each other as possible in size in each section.
the direction of rotation of the twisting device may be reversed at periodic reversal points, that is, after a length L of the twisted -unit has passed through the twisting device. It is also possible to rotate the twisting device in only one direction during twisting of the entire twisted unit. In such a case, it is advisable to rotate the twisting device intermittently in the same direction.
the length of the twisted unit positioned between the payout point B and the twisting device 4 does not become torsion free. If such length of the twisted unit does not become torsion free, a sufficient compactness of the elements 2 forming the twisted unit 1 is insured. It is therefore advisable, for practical reasons, that the drive of the twisting device be switched on again after a specific minimum length of the twisted unit 1 between the twisting device 4 and the payout point E has been reached.
the twisting device 4 rotates counterclockwise, for example, the section of the twisted unit is twisted to the right in front of said twisting device and the section of said twisted unit behind said twisting device is twisted to the left in accordance with the change in the right-hand twist. If the twisting device is then deenergized or stopped, the section of the twisted unit having the right-hand twist slips through said twisting device unaltered. In this way, the section of the twisted unit behind the twisting device in the direction of advance toward the take up point A, has a right-hand twist. At the same time, the righthand twist of the section in front of the twisting device is decreased.
the decrease in the right-hand twist is interrupted, however, at the proper instant by the reenergization or restarting of the twisting device.
the twisting device then rotates again to the right and again increases the right-hand torsion in the section of the twisted unit in front of said twisting device, thereby providing a left-hand torsion behind said twisting device.
the constant torsion in the section between the payout point E and the twisting device continuously holds the elements together in the twisted unit. This insures a smooth admanner without spreading said'tivisted unit perpendicularly to its axis by the portions of the twisting device which are shorter than the length of said twisted unit in the direction in which said twisting device is rotated.
the transfer of force from the twisting device to the twisted unit in the direction of rotation of said twisting device is executed advantageously by contact pressure which does not influence the passage of said twisted unit to any great extent.
two rollers may be positioned perpendicularly to the axis of the twisted unit and may be utilized for this purpose.
the rollers may be in contact with the twisted unit positioned between them and may be elastically urged toward vance of the twisted unit so that, if desired, the speed of advance may be increased.
the smooth advance of the twisted unit is'favorable to electrical decoupling of said twisted unit.
additional twisting devices besides the twisting device 4, are provided between the payout point E and the twisting device 4.
the additional twisting devices support the formation of a homogeneous stranding of the section of the twisted unit between the initial twisting device 4 and the pay out point E. In this manner, nonhomogeneous properties of the stranding due to lack of torsional elasticity of the twisted unit are avoided in those cases where the distance a between the twisting device 4 and the payout point E in FiG. I is relatively long.
FIG. 4 The embodiment of the present invention utilizing additional twisting devices is illustrated in FIG. 4.
the embodiment of FIG. 4 is a modification of the embodiment of FIG. 1.
additional twisting devices 42 and 43 are positioned between the initial twisting device 4 and the payout point B.
the additional twisting devices 42 and 43 are distributed over the distance a.
the twisting devices 42 and 43 support stranding of the section of the twisted unit 1 between the initial twisting device 4 and the payout point point E. This results in the provision of an extension of the freely twistable section of the twisted unit 1.
the additional twisting devices 42 and 43 need not be evenly spaced in the distance a. 0n the contrary, as indicated in FIG. 4, the additional twisting devices 42 and 43 may be unevenly spaced between the initial twisting device 4 and the payout point E.
a length of the twisted unit 1 be engaged in a nonpositive each other.
the rollers are rotated about the axis of the twisted unit.
FIG. 5 illustrates a pair of rollers functioning as a twisting device.
the twisted unit 1 comprises a plurality of elements 2, as provided in the embodiment of FIG. 1, for example.
the twisting device of FIG. 5 comprises two rollers 38 and 39 coplanarly positioned opposite each other in a plane perpendicular to the axis of the twisted unit 1.
a spring 40 is affixed at one end to the rotary shaft of the roller 38 and is afi'rxed at its outer end to the rotary shaft of the roller 39.
the spring 40 functions to urge the rollers 38 and 39 toward each other elastically and thereby urges said rollers into elastic contact with the twisted unit 1.
Each of the rollers 38 and 39 has a peripheral groove or channel formed around its circumference and the twisted unit 1 fits into said channels or grooves.
rollers 38 and 39 are rotated about the axis of the twisted unit 1, which twisted unit is advanced to the left, so that the twisting device comprising said rollers is rotated due to the stranding of said basic unit. It is of primary importance that the contact pressure of the rollers 38 and 39 on the twisted unit I resulting from the force of the spring 40 does not practically hinder the passage of said twisted unit through the twisting device.
twisting device Another advantage of the twisting device is that the transfer of force from said twisting device to the twisted unit is provided in the direction of rotation of said twisting device via a deflection of said twisted unit which functions as a lever relative to its axis.
the twisting device includes guide elements fixed by the direction of advance. FIG. 6 illustrates such a twisting device.
the twisted unit 1 is advanced in the direction of the arrow, toward the left, around a roller 41.
the roller 41 has a peripheral groove or channel formed in its circumference to accommodate the twisted unit 1 and is mounted for rotation on a rotary shaft positioned perpendicularly to the axis of the twisted unit 1.
the roller 41 is rotated about the axis of the twisted unit 1 determined by the direction of advance of said twisted unit so that said twisted unit is stranded.
FIGS. 7 and 8 illustrate an embodiment of a twisting device which has proven to be especially adaptable and suitable in field tests.
the transfer of force is effected by a deflection of the twisted unit functioning as a lever.
the twisting device comprises three rollers 30, 31 and 32 coplanarly positioned. The rollers 30, 31
Each of the rollers 30, 31 and 32 has a peripheral groove or channel formed around its circumference to accommodate the twisted unit 1.
the axis of the roller 31 is positioned between and beneath the axes of the rollers 30 and 32, so that the twisted unit passes between said rollers in a manner whereby said twisted unit is above the roller 31 and beneath the'rollers 30 and 32. Any suitable number of rollers may be utilized.
the twisting device is mounted on a stationary or fixed frame 12 via a roller bearing 11.
a flange 27 is fitted onto the rotatable peripheral part of the roller bearing 11 and is affixed to a disc 28 which functions as a chain or drive wheel.
the disc 28 may thus be driven via the flange 27 in any direction of rotation and at any desired speed via a drive chain, belt, or the like.
a support member 29 supports the three rollers 30, 31 and 32 which are mounted thereon.
the support member 29 is affixed to the disc 28.
the twisted unit 1 is deflected between the rollers 30 and 32, since it passes between said rollers and the roller 31 in a waving fashion, so that a leverlike force is produced perpendicularly to said twisted unit; said twisted unit being engaged by the three rollers of the twisting device and being thereby twisted or stranded.
roller support members fasten the roller support members to the frame of the apparatus with adjusting screws so that the diameter of the twisted unit 1 to be stranded may be correspondingly adjusted.
a further improvement is to cover the guiding channels or grooves of the rollers, which contact the twisted unit 1, with elastic material such as, for example, rubber. It is also advisable to flute the guiding channels or grooves of the rollers, preferably in V-shaped configuration corresponding to the diameter of the twisted unit 1.
the surfaces of the guiding channels or grooves of the rollers may also be provided with mutually parallel grooves parallel to the axis of the twisted unit, such grooves being considerably smaller than half the diameter of an element of said twisted unit.
the guide rollers utilized to transfer force in the direction of rotation of the twisting device may additionally be rotated about their axes. This facilitates the passage of the twisted unit 1 to be stranded through the twisting device.
Apparatus for stranding a twisted unit of a cable in different directions of stranding for individual lengths comprisin i plurality of cable elements
twisting means engaging said twisted unit in a nonpositive manner perpendicular to the axis of said twisted unit, said twisted unit being led to said twisting means in stretched rotatable condition, said twisting means rotating said twisted unit a number of twists between said payout point and said takeup point and providing a different direction of stranding of the twisted unit for individual section lengths, said twisting means engaging said twisted unit at a point closer to said takeup point than to said payout point, a section of said twisted unit having the same direction of stranding having a minimum length which is the length between said takeup point and the engagement point of said twisting means and a maximum length which is three times the length between said engagement point and said payout point.
Apparatus as claimed in claim 3 further comprising stranding means between said twisting means and said takeup point for stranding a plurality of twisted units, and wherein the regulation of said one of said speed and direction of rotation provides resultant stranding of said stranding means of uniform size and length.
said twisting means comprises spaced components on both sides of said twisted unit and said components contact said twisted unit with a pressure which does not hinder the passage of said twisted unit through said twisting means.
Apparatus as claimed in claim 1 further comprising additional twisting means between said payout point and said twisting means for providing homogeneous stranding of the section of said twisted unit between said payout point and said twisting means.
said twisting means comprises three spaced rollers mounted for coplanar rotation with their axes positioned in a manner whereby said twisted unit passes in contact with each of said rollers in curvilinear fashion.
a process for stranding a twisted unit of a cable in different directions of stranding for individual lengths comprising the steps of forming a twisted unit from a plurality of cable elements at a payout point;
twisting the twisted unit in a nonpositive manner perpendicular to the axis of said twisted unit a number of twists at a point between the payout point and a takeup point and providing a different direction of stranding of the twisted unit for individual section lengths when said twisted unit is in stretched rotatable condition at a point closer to the takeup point than to the payout point, a section of the twisted unit having the same direction of stranding having a minimum length which is the length between the takeup point and the twisting point and a maximum length which is three times the length between the twisting point and the payoutpoint.
each of the twisted units is twisted at aiiafyfifg one of speed and direction of rotation, the variation of twisting occurring at a time different from that of the others.
each of the twisted units is twisted at a twist point a distance from a corresponding takeup point and a distance from a corresponding payout point which have a different relation to each other from the others.

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Manufacturing & Machinery (AREA)
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US825647A 1968-05-21 1969-05-19 Apparatus and a method for stranding a twisted unit of a cable Expired - Lifetime US3593509A (en)

Applications Claiming Priority (1)

Application Number	Priority Date	Filing Date	Title
DE19681765452 DE1765452B1 (de)	1968-05-21	1968-05-21	Verfahren zum verseilen von verseilelementen fuer elektrische kabel oder leitungen zu einer verseileinheit mit abschnitt weise wechselnder verdrillungsrichtung

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Publication Number	Publication Date
US3593509A true US3593509A (en)	1971-07-20

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ID=5698443

Family Applications (1)

Application Number	Title	Priority Date	Filing Date
US825647A Expired - Lifetime US3593509A (en)	1968-05-21	1969-05-19	Apparatus and a method for stranding a twisted unit of a cable

Country Status (6)

Country	Link
US (1)	US3593509A (de)
JP (1)	JPS56557B1 (de)
AT (1)	AT297113B (de)
DE (1)	DE1765452B1 (de)
FR (1)	FR2009924A1 (de)
GB (1)	GB1244261A (de)

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US4056925A (en) *	1974-11-15	1977-11-08	Siemens Aktiengesellschaft	Method and apparatus for the SZ-twisting of electrical cables
US4182107A (en) *	1978-11-06	1980-01-08	Western Electric Company, Inc.	Method of forming S-Z twisted strand units
US4192127A (en) *	1978-09-28	1980-03-11	Exxon Research & Engineering Co.	Method and apparatus for making monofilament twines
US4196576A (en) *	1977-06-08	1980-04-08	Siemens Aktiengesellschaft	Method and apparatus for S-Z twisting of electrical cables
US4217750A (en) *	1977-10-21	1980-08-19	Hills Bruce W	Machine for twisting wire strands of electric cables
US4266398A (en) *	1978-06-28	1981-05-12	Siemens Aktiengesellschaft	Method and apparatus for the layerwise SZ twisting of elements of electrical or optical cables
US4272951A (en) *	1978-07-28	1981-06-16	Siemens Aktiengesellschaft	Apparatus for the SZ twisting of power cable conductors with sector-shaped conductor cross section
US4288976A (en) *	1978-07-28	1981-09-15	Siemens Aktiengesellschaft	Apparatus for the SZ-twisting of power cable conductors with sector-shaped conductor cross section
US4432196A (en) *	1981-03-18	1984-02-21	Felten & Guilleaume Carlswerk Aktiengesellschaft	Telephone cable
US4467596A (en) *	1981-12-08	1984-08-28	Siemens Aktiengesellschaft	SZ Twisting device for elements of electric cables and lines to be twisted

Families Citing this family (7)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
DE2833701C3 (de) *	1978-07-28	1982-03-25	Siemens AG, 1000 Berlin und 8000 München	Vorrichtung zum SZ-Verseilen von Verseilelementen elektrischer oder optischer Kabel und Leitungen
EP0007472B1 (de) *	1978-07-28	1982-06-02	Siemens Aktiengesellschaft	Vorrichtung zum SZ-Verseilen von Verseilelementen elektrischer oder optischer Kabel und Leitungen
DE2833707C2 (de) *	1978-07-28	1986-08-14	Norddeutsche Seekabelwerke Ag, 2890 Nordenham	Vorrichtung zur SZ-Vortorsion oder zur SZ-Verseilung von Verseilelementen elektrischer Kabel und Leitungen
DE2833706C2 (de) *	1978-07-28	1986-08-14	Norddeutsche Seekabelwerke Ag, 2890 Nordenham	Vorrichtung zur SZ-Vortorsion oder zur SZ-Verseilung von Verseilelementen elektrischer Kabel und Leitungen
DE3127375C2 (de) *	1981-07-09	1983-11-03	Siemens AG, 1000 Berlin und 8000 München	SZ-Verseilmaschine für Starkstromkabel und -leitungen
DD237021A1 (de) *	1985-05-06	1986-06-25	Thaelmann Schwermaschbau Veb	Verfahren zum sz-verseilen
CN112735688B (zh) *	2020-12-25	2022-05-03	江苏芸裕金属制品有限公司	一种可调节捻制方向以及捻制距离的自动管绞机

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US2790299A (en) *	1955-08-22	1957-04-30	Western Electric Co	Method and apparatus for twisting wires
US3025656A (en) *	1957-07-17	1962-03-20	Cook Foundation Inc	Method and apparatus for making communication cable
US3052079A (en) *	1958-11-10	1962-09-04	Western Electric Co	Apparatus for twisting strands
US3367097A (en) *	1966-06-16	1968-02-06	Anaconda Wire & Cable Co	Reverse twist strander, stranding method, and strand
US3412544A (en) *	1966-04-14	1968-11-26	Sumitomo Electric Industries	Apparatus for the manufacture of communication cable
US3434275A (en) *	1967-04-26	1969-03-25	Stanley Backer	Alternate twist yarns and method of forming same
US3507108A (en) *	1965-03-01	1970-04-21	Fujikura Ltd	Method of producing s-z alternating twists and the apparatus therefor

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BE568198A (de) *	1957-07-19
US3169360A (en) *	1962-07-02	1965-02-16	Anaconda Wire & Cable Co	Stranding apparatus and method
US5373550A (en) *	1992-10-13	1994-12-13	At&T Corp.	Transmission of check images by way of a public switched telephone network

1968
- 1968-05-21 DE DE19681765452 patent/DE1765452B1/de active Pending
1969
- 1969-02-24 JP JP1327869A patent/JPS56557B1/ja active Pending
- 1969-03-26 AT AT298569A patent/AT297113B/de not_active IP Right Cessation
- 1969-04-25 GB GB21371/69A patent/GB1244261A/en not_active Expired
- 1969-05-19 US US825647A patent/US3593509A/en not_active Expired - Lifetime
- 1969-05-19 FR FR6916136A patent/FR2009924A1/fr not_active Withdrawn

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US2790299A (en) *	1955-08-22	1957-04-30	Western Electric Co	Method and apparatus for twisting wires
US3025656A (en) *	1957-07-17	1962-03-20	Cook Foundation Inc	Method and apparatus for making communication cable
US3052079A (en) *	1958-11-10	1962-09-04	Western Electric Co	Apparatus for twisting strands
US3507108A (en) *	1965-03-01	1970-04-21	Fujikura Ltd	Method of producing s-z alternating twists and the apparatus therefor
US3412544A (en) *	1966-04-14	1968-11-26	Sumitomo Electric Industries	Apparatus for the manufacture of communication cable
US3367097A (en) *	1966-06-16	1968-02-06	Anaconda Wire & Cable Co	Reverse twist strander, stranding method, and strand
US3434275A (en) *	1967-04-26	1969-03-25	Stanley Backer	Alternate twist yarns and method of forming same

Cited By (11)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US4056925A (en) *	1974-11-15	1977-11-08	Siemens Aktiengesellschaft	Method and apparatus for the SZ-twisting of electrical cables
US4196576A (en) *	1977-06-08	1980-04-08	Siemens Aktiengesellschaft	Method and apparatus for S-Z twisting of electrical cables
US4217750A (en) *	1977-10-21	1980-08-19	Hills Bruce W	Machine for twisting wire strands of electric cables
US4266398A (en) *	1978-06-28	1981-05-12	Siemens Aktiengesellschaft	Method and apparatus for the layerwise SZ twisting of elements of electrical or optical cables
US4272951A (en) *	1978-07-28	1981-06-16	Siemens Aktiengesellschaft	Apparatus for the SZ twisting of power cable conductors with sector-shaped conductor cross section
US4288976A (en) *	1978-07-28	1981-09-15	Siemens Aktiengesellschaft	Apparatus for the SZ-twisting of power cable conductors with sector-shaped conductor cross section
US4192127A (en) *	1978-09-28	1980-03-11	Exxon Research & Engineering Co.	Method and apparatus for making monofilament twines
US4182107A (en) *	1978-11-06	1980-01-08	Western Electric Company, Inc.	Method of forming S-Z twisted strand units
WO1980001017A1 (en) *	1978-11-06	1980-05-15	Western Electric Co	Method of forming s-z twisted strand units
US4432196A (en) *	1981-03-18	1984-02-21	Felten & Guilleaume Carlswerk Aktiengesellschaft	Telephone cable
US4467596A (en) *	1981-12-08	1984-08-28	Siemens Aktiengesellschaft	SZ Twisting device for elements of electric cables and lines to be twisted

Also Published As

Publication number	Publication date
FR2009924A1 (fr)	1970-02-13
DE1765452B1 (de)	1971-04-01
GB1244261A (en)	1971-08-25
JPS56557B1 (de)	1981-01-08
AT297113B (de)	1972-03-10

Publication	Publication Date	Title
US3593509A (en)	1971-07-20	Apparatus and a method for stranding a twisted unit of a cable
US3491525A (en)	1970-01-27	Method for stranding in the manufacture of communication cables and stranding apparatus
US3507108A (en)	1970-04-21	Method of producing s-z alternating twists and the apparatus therefor
US3921381A (en)	1975-11-25	Method of manufacturing a cable using SZ twisting devices
US4056925A (en)	1977-11-08	Method and apparatus for the SZ-twisting of electrical cables
US3884024A (en)	1975-05-20	Twisting device for the SZ twisting of electrical cables
GB1188038A (en)	1970-04-15	Stranding of Elongate Elements
US3797217A (en)	1974-03-19	Method and arrangement for making sz-twisted cables
US3367097A (en)	1968-02-06	Reverse twist strander, stranding method, and strand
US3664108A (en)	1972-05-23	Intermediate storer for apparatus for stranding a twisted unit of a cable
GB1190811A (en)	1970-05-06	Improvements in or relating to Cable Manufacture
US2053645A (en)	1936-09-08	Strand handling apparatus
US3365871A (en)	1968-01-30	Accumulator stranding machine with two sets of wheels
US3941166A (en)	1976-03-02	Machine for alternate twisting of wire or cable
GB1184657A (en)	1970-03-18	Method of and Apparatus for Forming Stranded Cables.
GB1119361A (en)	1968-07-10	Improvements in or relating to methods and apparatus for crimping yarns
US2352781A (en)	1944-07-04	Traversing apparatus
US3360919A (en)	1968-01-02	Stranding apparatus
US4182107A (en)	1980-01-08	Method of forming S-Z twisted strand units
GB1126671A (en)	1968-09-11	Manufacture of wire strands
US1988586A (en)	1935-01-22	Quad stranding machine
US1684511A (en)	1928-09-18	Strand-twisting apparatus
US3475893A (en)	1969-11-04	Method of manufacturing communication cable and manufacturing apparatus
US3589118A (en)	1971-06-29	Intermediate storer disc for apparatus for stranding a twisted unit of a cable
US2834178A (en)	1958-05-13	Strand handling machine