Microcapillary Wire Coating Die Assembly

FIELD OF THE INVENTION

This invention relates to a microcapillary wire coating die assembly for the production of electrical and telecommunication cable jackets with microcapillary structures.

BACKGROUND OF THE INVENTION

Electrical and telecommunication cables are made of tough, polymeric materials designed for years of defect-free service and, accordingly, cable jackets are typically difficult to tear and require special cutting tools and trained installers for safe installation without damaging the cable. As such, there is a strong end-user need for ease of installation and “easy-peel” jackets for ready access to internal components, and easy connection of fiber optic cables, with the overall objective to reduce total system cost.

To this end, cable jackets with tear features have been developed. These structures provide easy peeling of the cable jacket so as to provide access to the cable internal components and easy connections between fiber optic cables. Products comprising tear features, and processes for making these products, are well known in the art. See, for example, WO 2012/071490 A2, US 2013/0230287 A1, U.S. Pat. Nos. 7,197,215, 8,582,940, 8,682,124, 8,909,014, 8,995,809, US 2015/0049993 A1, CN 103 665 627 A, and CN 201 698 067.

One tear feature of particular interest are microcapillaries. These structures are small diameter channels formed in the wall of the cable jacket at the time of its formation and that extend along the longitudinal axis of the cable jacket. Here too, the art is replete with disclosures regarding the nature and formation of microcapillaries. See, for example, WO 2015/175208 A1, WO 2014/003761 A1, EP 1 691 964 B 1, WO 2005/056272 A2, WO 2008/044122 A2, US 2009/0011182 A1, WO 2011/025698 A1, WO 2012/094315 A1, WO 2013/009538 A2, and WO 2012/094317 A1.

In the production of annular microcapillary products, typically the product, e.g., a cable jacket, has multiple layers two of which form around a microcapillary. Such products can be difficult to make due to the typically small, compact area of the die from which the product is formed. This, in turn, requires the use of a larger diameter die which adds to the capital and operating costs of the equipment. Of interest to the cable jacket industry is a die that will allow for the extrusion of a cable jacket comprising a single polymeric layer with embedded microcapillaries.

SUMMARY OF THE INVENTION

In one embodiment the invention is mandrel assembly comprising:

- (A) a housing comprising:
  - (1) a housing wire tubular channel extending along (a) the length of the housing, and (b) the longitudinal centerline axis of the housing;
  - (2) a fluid annular channel encircling the wire tubular channel;
  - (3) a fluid ring in fluid communication with the fluid annular channel, the fluid ring positioned at one end of the housing; and
- (B) a cone-shaped tip having a wide end and a narrow end, the wide end of the tip attached to the end of the housing at which the fluid ring is positioned, the tip comprising:
  - (1) a tip wire tubular channel extending along (a) the length of the tip, and (b) the longitudinal centerline axis of the tip;
  - (2) a tip fluid channel in fluid communication with the fluid ring; and
  - (3) one or more nozzles in fluid communication with the tip fluid channel, the nozzles located at the end and extending beyond the narrow end of the tip;
    
    the housing wire tubular channel and the tip wire tubular channel in open communication with one another such that a wire can pass from one to the other in a straight line and without interruption.

In one embodiment the invention is a die assembly for applying a polymeric coating comprising microcapillaries to a wire or optic fiber, the assembly comprising the mandrel assembly described above.

In one embodiment the invention is wire coating apparatus for applying a polymeric coating comprising microcapillary structures to a wire or optic fiber, the apparatus comprising the die assembly described above.

In one embodiment the invention is a wire or optic fiber comprising a polymeric coating comprising microcapillary structure, the polymeric coating applied to the wire or optic fiber using the apparatus described above.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a perspective view of a die assembly for extruding a cable jacket.

FIG. 1B is a sectional view of the die assembly of FIG. 1A.

FIG. 1C is an exploded view of the die assembly of FIGS. 1A and 1B.

FIG. 2A is a perspective view of a microcapillary mandrel assembly.

FIG. 2B is a sectional view of the microcapillary mandrel assembly of FIG. 2A.

FIG. 2C is an exploded view of the microcapillary mandrel assembly of FIGS. 2A and 2B.

FIGS. 3A-3D are schematic views of the placement of microcapillary channels in the wall of a cable jacket.

FIG. 4 is a micrograph of a wire jacket with two microcapillary channels prepared with air as described in the Example.

FIG. 5 is a micrograph of a wire jacket without microcapillary channels prepared without air as described in the Example.

FIGS. 6A and 6B are photographs of inventive and comparative, respectively, coated wire tear samples from the Example.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

For purposes of United States patent practice, the contents of any referenced patent, patent application or publication are incorporated by reference in their entirety (or its equivalent U.S. version is so incorporated by reference) especially with respect to the disclosure of definitions (to the extent not inconsistent with any definitions specifically provided in this disclosure) and general knowledge in the art.

The numerical ranges disclosed herein include all values from, and including, the lower and upper value. For ranges containing explicit values (e.g., 1 or 2; or 3 to 5; or 6; or 7), any subrange between any two explicit values is included (e.g., 1 to 2; 2 to 6; 5 to 7; 3 to 7; 5 to 6; etc.).

The terms “comprising,” “including,” “having,” and their derivatives, are not intended to exclude the presence of any additional component, step or procedure, whether or not the same is specifically disclosed. In order to avoid any doubt, all compositions claimed through use of the term “comprising” may include any additional additive, adjuvant, or compound, whether polymeric or otherwise, unless stated to the contrary. In contrast, the term, “consisting essentially of” excludes from the scope of any succeeding recitation any other component, step, or procedure, excepting those that are not essential to operability. The term “consisting of” excludes any component, step, or procedure not specifically delineated or listed. The term “or,” unless stated otherwise, refers to the listed members individually as well as in any combination. Use of the singular includes use of the plural and vice versa.

“Hybrid cable” and similar terms means a cable that contains two or more types of dissimilar transmission media within a single cable construction. Hybrid cables include, but are not limited to, cables containing a metallic wire such as copper twisted pairs and one or more optic fibers, or an optical fiber and a coaxial transmission construction.

“Cable”, “power cable” and like terms mean at least one wire or optical fiber within a sheath (e.g., an insulation covering and/or a protective outer jacket). Typically, a cable is two or more wires or optical fibers bound together, typically in a common insulation covering and/or protective jacket. The individual wires or fibers inside the sheath may be bare, covered or insulated. The cable can be designed for low, medium, and/or high voltage applications. Typical cable designs are illustrated in U.S. Pat. Nos. 5,246,783; 6,496,629 and 6,714,707.

“Conductor” denotes one or more wire(s) or fiber(s) for conducting heat, light, and/or electricity. The conductor may be a single-wire/fiber or a multi-wire/fiber and may be in strand form or in tubular form. Nonlimiting examples of suitable conductors include metals such as silver, gold, copper, carbon, and aluminum. The conductor may also be optical fiber made from either glass or plastic.

Unless stated to the contrary, implicit from the context, or customary in the art, all parts and percents are based on weight and all test methods are current as of the filing date of this disclosure.

“In fluid communication” and like terms means that adjoining devices are connected in a manner such that a fluid can pass from one to the other without interruption.

“In open communication” and like terms means that adjoining devices are connected in a manner such that an object can pass from one to the other without interruption.

FIGS. 1A-1C illustrate a typical microcapillary wire coating apparatus. Wire coating apparatus 10 comprises end cap 11 securely attached to one end of housing 12. Fitted within end cap 11 is die 13 held in place by die retainer 14 and die retainer retaining screws 15, which are used for adjusting the wire jacket thickness uniformity and centricity.

Microcapillary mandrel assembly 16 is fitted within and extends through housing 12. Microcapillary mandrel assembly 16 is fitted within housing 12 by means of mandrel retaining screw 17, mandrel retainer 18, and adjustment screw 19. Fitted about microcapillary mandrel assembly 16 within housing 12 is resin flow deflector 20. Spacer 21 maintains the desired distance between die 13 and housing 12.

FIGS. 2A-2C illustrate one embodiment of the microcapillary mandrel assembly of this invention. Microcapillary mandrel assembly 16 comprises mandrel body 22, mandrel tip 23, mandrel adaptor 24, and mandrel adaptor retaining screw 25. Mandrel tip 23 and mandrel adaptor retaining screw 25 are attached to opposite ends of mandrel body 22 typically in a threaded relationship with a high temperature thread sealant between the opposing threads of the body and screw. Mandrel adaptor 24 is secured to mandrel body 22 by means of adaptor retaining screw 25.

Mandrel body 22 comprises wire channel 26a and fluid channel 27. Wire channel 26a is tubular and fluid channel 27 is annular, and fluid channel 27 circumscribes wire channel 26a. Both channels run the length of mandrel body 22. Fluid channel 27 provides fluid communication between mandrel adaptor 24 and mandrel tip 23, and fluid channel 27 terminates in fluid ring 28 located at the juncture of mandrel body 22 and mandrel tip 23.

Mandrel tip 23 is a cone with the narrow or tapered end equipped with nozzles 29a and 29b. These nozzles extend beyond the tapered end of mandrel tip 23. Mandrel tip 23 comprises fluid channels 30a and 30b, and these channels run the length of mandrel tip 23 and provide fluid communication between fluid ring 28 and nozzles 29a and 29b, respectively. Mandrel tip 23 is also comprises wire channel 26b that runs the length of mandrel tip 23 and is aligned with and is in open communication with wire channel 26a of mandrel body 22. Wire channel 26b is positioned along the center, longitudinal line of mandrel tip 23, and fluid channels 30a and 30b are positioned about wire channel 26b following the taper line of mandrel tip 23 beginning at fluid ring 28 and terminating at nozzles 29a and 29b, respectively. These nozzles are positioned about and beyond the tapered end of mandrel tip 23.

Mandrel adaptor 24 and mandrel adaptor retaining screw 25 comprise wire channel 26c and 26d, respectively. When assembled, wire channels 26a-26d are in alignment and in open communication with one another such that a wire can enter wire channel 26d and pass through wire channels 26a-26c in a straight line and without interruption. Mandrel adaptor 24 is also equipped with fluid port 31 which is in fluid communication with fluid channel 27 of mandrel body 22. Mandrel body 22 is also equipped with polymer melt port 32 which is in fluid communication with polymer melt channel 33 formed by the exterior surface of mandrel assembly 16 and the interior surfaces of mandrel body 22 and mandrel tip 23.

Wire coating apparatus 10 is operated in the same manner as known wire coating apparatus. Wire or previously coated wire, e.g., a wire comprising one or more wire coatings such as one or more semiconductor layer and/or insulation layers is fed into mandrel adaptor retaining screw wire channel 26d and drawn through wire channels 26a-c. The wire itself can comprise one or more strands, e.g., a single strand or a twisted pair of strands, of any conductive metal, e.g., copper or aluminum, or optic fiber.

Polymer melt is fed, typically under pressure, to mandrel body 22 through polymer melt port 32, and deflected into polymer melt channel 33 by resin flow deflector 20. Typically the wire coating apparatus is attached to the exit end of an extruder from which it receives the polymer melt. The polymer itself can be selected from any number of thermoplastic and thermoset materials, the specific material selected for its end-use performance. Exemplary materials include various functionalized and nonfunctionalized polyolefins such as polyethylene, polypropylene, ethylene vinyl acetate (EVA), and the like. The polymer melt flows through polymer melt channel 33 until it flows around nozzles 29a-b and is applied to the surface of the wire.

Fluid, typically air but any gas, liquid or melt can be used, enters, typically under pressure, fluid channel 27 through fluid port 31 of mandrel adaptor 24. The fluid moves through fluid channel 27 of mandrel body 22 into fluid ring 28 from which it enters fluid channels 30a-b of mandrel tip 23. The fluid exits channels 30a-b through nozzles 29a-b, respectively, into the polymer melt as the melt is applied to the wire. Because the nozzles extend beyond the end of the cone of mandrel tip 23, the fluid from nozzles 29a-b enters the wire covering and as the polymer melt solidifies, forms microcapillaries in the covering. The number of microcapillaries formed is a function of the number of nozzles extending beyond the end of the cone of the mandrel tip. Likewise, the placement of the microcapillaries in the wire covering is a function of the placement of the nozzles on the mandrel tip. FIGS. 3A-D illustrate four placement patterns in a cable jacket formed with a mandrel tip equipped with two nozzles. In each figure the microcapillaries are opposite one another, but in FIG. 3A they are centered in the jacket wall, while in FIG. 3B they are on the inner surface of the jacket wall, while in FIG. 3C they are near the outer surface of the jacket wall, while in FIG. 3D they are on the outer surface of the jacket wall (and thus actually form a groove in the outer surface of the jacket wall).

The placement of the nozzles such that they extend beyond the end of the cone of the mandrel tip allows for the formation of microcapillaries in the wall of the wire coating. This, in turn, allows for the extrusion of a single layer of wire coating with microcapillaries which, in turn, allows for the design of a die with a smaller diameter as compared to a die for extruding multiple layers with microcapillaries formed between the layers. This, in turn, can reduce both the capital and operating costs associated with extruding a coating about a wire.

The microcapillary geometry can be optimized to fit covering thickness and achieve desired ease of tearing with minimum impact on mechanical properties. The microcapillaries can be discontinuous or intermittent so to enable jacket tearing over a specific length. The microcapillaries can be placed at desired radial positions on the jacket circumference (as illustrated in FIGS. 3A-D). The microcapillaries can be marked for ease of finding by printing or indentation or embossing the exterior surface of the wire covering. The microcapillary can be also filled with a substantially weaker non-covering polymeric material, such as an elastomer, by using a secondary extruder to pump the polymer melt into microcapillary channels. The short axis of microcapillary should not exceed the thickness of the jacket or cable layer containing it. The microcapillary geometry is controlled by flow rate and pressure, e.g., air flow rate and air pressure.

The following example is a further illustration of an embodiment of this invention.

EXAMPLE

The wire coating apparatus used in this example is described in FIGS. 1A-C and 2A-C. The resin flow deflector distributes the incoming polymer melt into uniform flow across the annular channel. Air is introduced to microcapillary mandrel through the mandrel adaptor, and it is transported to the mandrel tip via hollow channel. The air is divided into two streams, and then it arrives at the microcapillary nozzles. The polymer melt wraps around microcapillary nozzles and meets with air at the die exit.

The wire coating apparatus was a Davis-Standard wire coating line comprised of a single-screw extruder, a wire stranding unit, a microcapillary tubing type cross-head die, an air-line for providing air flow to the microcapillary channels, a series of water bathes with temperature controllers, and a filament take-up device.

The polymer resin used is a medium density polyethylene (MDPE) compound (AXELERON™ GP 6548 BK CPD) with a density 0.944 g/cm³and a melt flow rate of 0.7 g/10min (190° C., 2.16 kg). The temperature profile of the extrusion line is reported in Table 1. The air pressure was initially set to 20 pounds per square inch (psi) (137,896 Pascals) and air flow rate was set to 84.7 cc/min for starting up the extrusion. Using a conventional wire stranding unit, a 14 gauge (0.064 inch) copper wire was drawn through the microcapillary wire coating die. The wire was preheated to 225-250° F. before arriving at the die. Polymer pellets were fed into the extruder through a hopper, and then melted and pumped into the microcapillary cross-head die. The molten polymer flowed around microcapillary nozzles close to the die exit and was applied onto the surface of the copper wire. This coated wire was threaded through a series of water cooling troughs. The wire thus manufactured was collected on a filament take-up device. The air pressure and air flow rate were slowly regulated down so that that the extrusion coating process could be run in the steady state. For the inventive samples, the screw speed was changed from 18.5 revolutions per minute (rpm) to 45.75 rpm, and the line speed varied from 100 feet per minute (ft/min) to 300 ft/min (30.48 meters per minute (m/min) to 91.44 m/min). The air pressure was kept at 10 psi (68,948 Pascals), while the air flow rate varied from 15 cc/min to 23.1 cc/min.

For comparative samples, the air was shut off but the same extrusion conditions as inventive samples were kept.

TABLE 1

Temperature Profile of Extrusion Line for Making Microcapillary Wire Coating

Zone #1
Zone #2
Zone #3
Zone #4
Zone #5
Heat
Die 1
Die 2

(° C.)
(° C.)
(° C.)
(° C.)
(° C.)
(° C.)
(° C.)
(° C.)

160
179
193
210
210
216
216
216

The detailed processing conditions and jacket and microcapillary dimension are given in Table 2. FIGS. 4 and 5 show examples of inventive microcapillary wire jacket, which was prepared by the conditions of a screw speed of 30.5 rpm, a line speed of 200 ft/min (60.96 m/min), an air pressure of 10 psi (68,948 Pascals) and air flow rate of 15 cc/min, and comparative wire jacket, which was prepared by the conditions of a screw speed of 30.5 rpm and a line speed of 200 ft/min (60.96 m/min).

The strip test was conducted to measure the tear strength of inventive microcapillary jackets and comparative solid jackets. The specimens were cut by 1.0 inch (2.56 cm) opening to make the lips. As reported in Table, Comparative 11A solid jacket has the highest strip force of 13.18 (pound-foot (lbf) (58.63 Newtons (N)), while Inventive 7A with two microcapillary channels shows the lowest strip force of 3.37 lbf (15 N). This represents 75% reduction in strip force for Inventive 7A as compared with Comparative 11A. Microcapillary channels in Inventive 9A guide the tearing path and result in clean stripping with lower force, as displayed in FIG. 6A. In contrast, Comparative 11A solid jacket showed the breakage in a non-controlled fashion (FIG. 6B). Also as shown from Table 2, there is a strong correlation between strip force and total microcapillary wall thickness. Smaller wall thickness results in lower strip force.

TABLE 2

Processing Conditions, Jacket and Microcapillary Dimension, and Tear Strength of

Microcapillary Wire Jackets and Comparative Solid Jackets

Strip

Total
Force,

Air
Largest
Smallest
Jacket

Microcapillary
Avg.
StdDev-

Screw
Line
Air
Flow
Jacket
Jacket
Inner
Total
Wall
Peak
Peak

Speed
Speed
Pressure
Rate
Thickness
Thickness
Diameter
Microcapillary
Thickness
Load
Load

Sample #
(rpm)
(ft/min)
(psi)
(ccm)
(μm)
(μm)
(μm)
Area (μm²)
(μm)
(lbf)
(lbf)

Inventive 1A
18.5
100
10
23.1
913
691
1653
331924
609
4.21
0.32

Inventive 1B
18.5
100
10
23.1
921
665
1608
332930
581
3.88
0.29

Inventive 2A
18.5
100
10
18.3
833
574
1589
198252
570
3.86
0.04

Inventive 2B
18.5
100
10
18.3
586
683
1684
123428
711
3.65
0.09

Inventive 3A
22.5
100
10
18.3
571
676
1677
122803
707
4.37
0.30

Inventive 3B
22.5
100
10
18.3
1130
792
1617
512099
533
4.27
0.28

Inventive 4A
22.5
100
10
15
1076
726
1554
443609
549
4.57
0.06

Inventive 5A
26.5
100
10
15
1330
715
1558
428200
558
4.84
0.23

Inventive 6A
30.5
100
10
15
1436
842
1629
461629
538
5.80
0.19

Inventive 7A
30.5
200
10
15
731
550
1609
222874
478
3.37
0.10

Inventive 8A
45.75
300
10
15
751
552
1669
179180
544
3.77
0.22

Inventive 9A
45.75
300
Air Off

687
635
1593
19951
960
3.70
0.24

Inventive 9B
45.75
300
Air Off

672
546
1633
15665
971
5.38
1.13

Comparative 10A
30.5
200
Air Off

655
701
1588

6.05
0.64

Comparative 11A
30.5
100
Air Off

1143
1136
1646

13.18
0.47

Comparative 12A
26.5
100
Air Off

989
988
1594

11.43
0.42

Inventive 13A
26.5
100
10
15
1173
761
1586
359560
751
5.15
0.34

Microcapillary Wire Coating Die Assembly

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