Elastomeric core/staple fiber wrap yarn

A jet spun twistless core/wrapped elastic yarn product. The core yarn of the core/wrapped yarn is a unitary elastomeric filament. The core yarn is contiguously provided around the core with staple fibers. The inner portion of the staple fibers extends in the same direction as the elastomeric core and an outer wrapper portion of the staple fibers is helically wound around and holds the inner portion of the staple fibers on the core.

BACKGROUND OF THE INVENTION 
The present invention relates to a system for forming elastomeric 
core/staple fiber wrap yarn using an air jet spinning machine. The present 
system all but renders obsolete all current methods for forming 
elastomeric core/wrap yarns. 
It has been known in the textile industry to form core/wrap yarns, 
consisting of a single elastomeric core having a multiple staple fiber 
wrap wound therearound, e.g., Lycra.RTM. spandex core/cotton wrap yarn, 
encapsulating the core with an external sheath of fiber. Such core/wrap 
yarns are suitable for use in stretch apparel such as bathing suits, 
undergarments, hosiery, or other snugly fitting clothing items or 
comfortable regular fitting clothing. These core/wrap yarns have been 
formed by such methods as wrap spinning and sliver or roving fed ring 
spinning. However, these methods are very labor intensive and thus 
expensive, and the quality of the end product is lower than desired for 
high speed mass production. 
In recent years, the industry has turned to air jet spinning to produce 
synthetic and blend yarns used extensively in the apparel industry. 
Currently, Murata Machinery Ltd., Kyoto, Japan, manufactures an air jet 
spinner sold under the trade name MJS, which can form synthetic and 
cotton/synthetic blend yarns. Although it has been desired to use a 
machine like the Murata MJS machine to form core/wrap yarns like 
spandex/cotton yarns, no one has ever successfully adapted a machine like 
the MJS machine to allow fully automated, trouble-free mass-production of 
such yarns. 
A single spinner station or so-called spindle of the MJS system is shown 
schematically in FIG. 1 (reproduced from U.S. Pat. No. 4,517,794, the 
entire disclosure of which is incorporated herein by reference). A sliver 
supply container 28 is provided behind a drafting assembly 11 for 
supplying raw material/substrate sliver S to the spindle. The drafting 
assembly 11 is a three-roller drafting system including rear rollers 8, 
apron rollers 9 and front rollers 10. The rear rollers 8 deliver the 
sliver to the apron rollers 9. The apron rollers 9 are rotating faster 
than the rear rollers 8 to stretch, draft, orient and flatten the sliver. 
The front rollers 10 are rotating even faster than the apron rollers 9 to 
draw the sliver at a desired ratio. Additional rollers can be added 
between the rear rollers 8 and apron rollers 9 to provide a four- or 
five-roller drafting assembly. 
The sliver is delivered from the front rollers 10 to an air jet nozzle 12, 
which, as shown conceptually in FIG. 2, includes two air jets 12a,12b, 
which air wrap the fibers which form the yarn in the same or opposite 
directions. As is known in the art, the jet spinners twist wrapper fibers 
from the sliver to provide a tightly wound yarn which is then taken up on 
a take-up roll 22 provided in take-up assembly 21,22,23. As is also known 
in the art, the take-up assembly includes a yarn clearer sensor 3, e.g., a 
Seletex.TM. sensor, which optically or capacitively monitors the quality 
of yarn exiting the air jet nozzle 12. 
The MJS includes an automatic knotter 7, which, in the event of breakage of 
yarn Y, will automatically grasp yarn from the exit of the air jet nozzle 
12 via suction hose 24 and splice or knot that yarn with yarn already 
wound on the take-up roll 22. A suction pipe 25 removes yarn from the 
take-up roll, and the two yarns are combined by splicing or knotting 
mechanism 27. See U.S. Pat. No. 4,517,794 for an explanation of the 
remaining components shown in FIG. 1 herein. 
In a typical MJS machine, which includes perhaps 60 separate side-by-side 
spindles, the knotter can travel up and down the machine line to service 
any individual spindle. In the event of yarn breakage, the microprocessor 
for the spindle on which the yarn breakage occurred sends a signal to the 
knotter, and the knotter then travels down the machine line until it 
contacts a microswitch located on the back of the spindle in need of 
servicing. Once the knotter is in position, the yarns are joined together 
via the splicing or knotting device 27. 
Murata has several patents on the air jet nozzle and the splicing or 
knotting mechanism. See, for example, U.S. Pat. Nos. 5,159,806, 4,246,744, 
4,263,775, 4,292,796, 4,411,128 and 4,481,761, each of which is fully 
incorporated herein by reference. 
In the operating manual for the Murata 802MJS it is alleged that Murata has 
a system capable of forming core/wrap yarn having a filament (i.e., 
non-elastic) yarn core and a staple fiber wrap. While, that system is not 
actually known to the present applicants, it is believed to require manual 
threading in the event of yarn breakage, a condition that occurs quite 
frequently, or is. not reliable for automatic re-threading. A cutter cuts 
out bad quality yarn if a defect is detected. Accordingly, the alleged 
Murata filament feed system is not suitable for mass production. 
SUMMARY OF THE INVENTION 
It is an object of the present invention to provide a core yarn feeding 
system to be used with the MJS system, which facilitates efficient 
production of core/wrap yarns, e.g., Lycra.RTM. spandex core/cotton wrap 
yarns. 
It is another object of the present invention to provide a system for 
forming elastomeric core/wrap yarn using an air jet spinning machine, 
comprising: 
threading means for feeding elastomeric yarn to a drafting zone of an air 
jet spinning machine; 
feed means for providing a controlled supply of elastomeric yarn to said 
threading means; and 
elastomeric yarn sensing means provided between said threading means and 
said feed means or as part of said threading means for detecting the 
presence of the elastomeric yarn passing from said feed means to said 
threading means; 
wherein the elastomeric yarn and sliver fed through the drafting zone are 
combined in an air jet nozzle of the air jet spinning machine to form an 
elastomeric core/wrap yarn. 
It is yet another object of the present invention to provide a package feed 
device for delivering yarn from a cylindrical creel package to a material 
handling device, comprising: 
a vertically oriented mounting plate having a front surface and opposed 
rear surface, and upper and lower portions; 
a drive roller extending substantially perpendicularly from said lower 
portion of said front surface of said mounting plate; 
means for rotating said drive roller at a desired speed; 
a creel package tube holder subassembly extending substantially 
perpendicularly from said upper portion of the front surface of said 
mounting plate, to carry said creel package; and 
means for biasing said creel package tube holder subassembly toward said 
drive roller to provide constant contact between the outer peripheral 
surface of the cylindrical creel package and said drive roller. 
It is still another object of the present invention to provide a sensor for 
sensing the presence and motion of a moving yarn or thread, comprising: 
a housing; 
rotatable wheel means provided on said housing and having opposed metal 
side surfaces; and 
means for generating magnetic eddy currents through said opposed metal side 
surfaces to inhibit rotation of said wheel means at high rotational 
speeds. 
It is yet another object of the present invention to provide a sensor for 
sensing the presence and motion of a moving yarn or thread, comprising: 
a housing; 
rotatable wheel means provided on said housing for rotation by a moving 
yarn or thread; and 
means for sensing the rotational speed of said wheel means. 
It is still another object of the present invention to provide a drafting 
assembly for conveying yarn, comprising: 
a main body frame; 
roller means for conveying a first yarn, said roller means comprising a 
pair of opposed apron rollers and a pair of opposed front rollers; 
clearer means for removing fibrous debris from at least one of said pair of 
opposed apron rollers; 
front roll wrap sensor means for sensing a yarn wrap condition on at least 
one of said pair of opposed front rollers; and 
threading means for introducing a second yarn to said front rollers. 
The present invention will be explained in more detail below with reference 
to the following drawings.

DETAILED DESCRIPTION OF THE INVENTION 
FIG. 3 shows a side view of a single spindle of a Murata MJS machine, 
modified to include the features of the present invention. Like numerals 
represent like structure or elements in FIGS. 1 and 3. The improvements 
which the present inventors have made to the MJS machine to enable mass 
production of elastomeric core/wrap yarn are collectively referred to 
hereinafter as a yarn feed system, although each individual component of 
the system has other utilities in addition to that explained herein. 
The yarn feed system includes a package drive assembly 40, yarn motion and 
presence sensor 41, an improved drafting assembly 42 and a yarn clearer 
(e.g., Seletex.RTM.) delay cylinder 43. An elastomeric yarn 44 is 
delivered from the package drive assembly 40, over the sensor 41 and into 
the drafting assembly 42. The elastomeric yarn 44 is combined with the 
sliver S in the air jet spinner nozzle 12 to form a core/wrap elastomeric 
yarn product. A vacuum exhaust conduit 31 is provided for removing stray 
or excess sliver from the area around the spinner nozzle 12. The core/wrap 
yarn exits the nozzle 12, passes over the yarn clearer delay cylinder 43, 
yarn clearer sensor 3, and is wound on take-up roll 22 in a conventional 
manner. 
Each component of the yarn feed system is explained below herein. 
Package Drive Assembly 
FIG. 4 is a side view of the yarn supply creel package drive assembly 40 
according to the present invention. The drive assembly has a mounting 
plate 51 which is positioned above an individual spinner station as shown 
in FIG. 3. The mounting plate 51 is oriented substantially perpendicular 
to the horizontal plane of the floor on which the spinner station is 
positioned. A slide block slot 52 is formed in the center region of the 
thickness of mounting plate 51, and a slide block 53 is positioned in the 
slot 52. FIG. 5A, which is a front view of the package drive assembly of 
FIG. 4 without the creel package 50 and package tube holder 56, shows that 
the slide block slot 52 is substantially rectangular in shape and extends 
vertically in the length direction of the mounting plate 51. The slide 
block 53 can move up and down in the slot 52. 
A creel package tube holder shaft slot 54 is formed through the front face 
51a of the mounting plate 51 to communicate with the slide block slot 52. 
FIG. 5A shows that the slot 54 is substantially concentric with the slot 
52, and that the slot 54 is oblong and extends vertically along the length 
of the mounting plate 52. A package tube holder shaft 55 extends through 
slot 54 and is fixed in the front surface 53a of slide block 53. A freely 
rotating package tube holder 56 is arranged on shaft 55, and the axes of 
both holder 56 and shaft 55, collectively the creel package tube holder 
subassembly, are oriented substantially perpendicularly to mounting plate 
51. 
A first tab 57 extends perpendicularly from rear surface 51b of mounting 
plate 51 in a region spaced below and in alignment with the major axis of 
the oblong slot 54. A second tab 58 extends perpendicularly from rear 
surface 53b of slide block 53 and is spaced above and in alignment with 
the major axis of the oblong slot 54. Another slot (not shown) is formed 
in rear face 51b of mounting plate 51 so that tab 58 can be fixed to slide 
block 53. A coil spring 59 connects the first and second tabs to bias the 
package tube holder subassembly 55,56 in a vertically downward direction. 
Tab 58 is positioned above the axis of shaft 55 to relieve some of the 
cantilever forces applied to shaft 55 by the weight of creel package 50. 
A package drive roller 60 is positioned on mounting plate 51 below the 
package tube holder subassembly. A shaft 61a of a stepper drive motor 61 
passes through mounting plate 51 and extends perpendicularly from the 
front face 51a thereof. The package drive roller 60 is fixed to shaft 61a 
of motor 61 such that drive roller 60 also extends perpendicularly from 
the front face 51a of mounting plate 51. FIG. 5A shows that the axis of 
the drive roller 60 and the axis of the package tube holder shaft 55 are 
preferably located in the same vertical plane. 
To operate the package feed mechanism of the present invention, a creel 
package 50 is mounted on package tube holder 56 so that the outer 
peripheral surface of the creel package contacts drive roller 60. Oblong 
slot 54 and slot 52 allow vertical movement of shaft 55 and slide block 
53, to accommodate creel packages of various diameters. Coil spring 59, 
along with normal gravitational forces, provides sufficient pressure 
between creel package 50 and drive roller 60 to enable the drive roller to 
drive the creel package to meter yarn from the creel package at a desired 
constant speed. 
The yarn wound on creel package 50 is drawn at nip 62 formed between drive 
roller 60 and creel package 50. The yarn is then fed over yarn sensor 41 
and into the thread-up device of drafting assembly 42. The speed of motor 
61 is controlled by a microprocessor-based printed circuit board 310 
(described below) to correspond to the speed of the other components of 
the spindle. The extent of drafting or stretching of the spandex yarn can 
be changed by adjusting an electronic setting at the end of the machine. 
This one setting controls all the spindles on the machine. As yarn is 
drawn off creel package 50, the diameter of the creel package decreases 
and the package holder subassembly moves in the vertically downward 
direction. That is, slide block 53 moves down slot 52 and shaft 55 moves 
down oblong slot 54. This movement is encouraged by the biasing provided 
by spring 59 and normal gravitational forces, such that sufficient 
pressure is always provided between creel package 50 and drive roller 60. 
Such pressure is desirable to insure that drive roller 60 positively 
drives creel package 50 and uniformly delivers a continuous supply of yarn 
from the creel package to the thread-up device at a desired constant yarn 
speed. 
In a preferred embodiment of the invention the creel package holds 
elastomeric yarn, e.g., spandex. Due to the high elasticity of spandex, 
the motor 61 should have a high acceleration rate up to the desired 
feeding speed to insure that no stretch component breakage of the yarn 
occurs during start-up of an individual spindle. It will be appreciated by 
those skilled in the art that this package drive assembly permits feed 
creels of yarn, such as highly elastomeric spandex, to be used, as 
received from the yarn manufacturer without any re-winding or processing 
before such yarn is fed into an air jet spinning machine for incorporation 
into a core/wrap elastomeric yarn. The package drive assembly of the 
present invention also can be used to deliver any type of yarn or thread 
to a yarn or thread processing machine, such as an air jet spinner. 
The stepper drive motor 61 is specially designed with a skewed rotor and 
avoids the use of a gear train or expensive frequency invertor. The 
vibration dampening ability of the creel package on the drive roll and the 
skewed rotor avoid resonance frequencies than can cause this type of motor 
to break lock or stall. 
FIG. 5B shows a modified version of the package drive assembly, wherein two 
auxiliary rollers 60a and 60b have been added. The auxiliary rollers 
prevent tension and extension yarn loss back to package 50. The avoidance 
of such tension loss reduces spandex end entrapment on the creel package 
which can cause unnecessary end breakage, thus reducing machine 
efficiency. The auxiliary rollers are driven by the drive roller 60 via 
belts. That is, an endless drive belt is connected directly between drive 
roller 60 and second auxiliary roller 60b, while a second belt, twisted in 
a figure-eight, is connected between drive roller 60 or second auxiliary 
roller 60b and first auxiliary roller 60a. Thus, first auxiliary roller 
60a rotates in a direction opposite to that of drive roller 60 and second 
auxiliary roller 60b. One or more of the rollers may have grooves therein 
for positioning the belts. The path of the yarn 44 is shown in FIG. 5B. 
These auxiliary rollers also may be driven electronically, via a motor, 
but belts are typically used to avoid additional expense. 
Yarn Motion and Presence Sensor 
While it has been known to use optical or capacitive sensors in textile 
machines, e.g., Peyer, Loepfe, Uster, or Seletex.RTM. yarn clearers, to 
detect the presence and quality of yarn, elastomeric yarns present unique 
sensing problems. The elastomeric yarn used in the present invention 
typically is drawn at a ratio that reduces the yarn denier to as low as 3 
denier, which is finer than human hair. Moreover, since spandex cannot be 
dyed, it is sometimes desirable to use clear spandex yarn to avoid visual 
detection in the final product. It is difficult to detect such fine yarn, 
and indeed virtually impossible to detect or see clear yarn with known 
optical or capacitive sensors used in the textile industry. The yarn 
motion and presence sensor of the present invention not only can provide 
precise detection of such clear and fine yarns, but is useful for 
detecting all types of moving yarn and thread. 
The yarn sensor of the present invention incorporates two novel concepts: 
(1) the use of photomicrosensors to detect rotational speed of an idler 
wheel, and (2) the use of magnetic eddy currents to provide instantaneous 
braking of the idler wheel at high speed with minimal braking at low 
speed. 
FIG. 6 is a cross-sectional view of the motion and presence sensor 41 of 
the present invention. The sensor includes a transparent housing 100 
preferably having a prism shaped outer sector 101 and a recessed bottom 
102. A shaft 103 protrudes from a side surface 104 of the housing 100. The 
side surface 104 has a circular recess 105 therein centered around the 
shaft 103. A notch idler wheel 106 is mounted on the shaft 103 and is 
freely rotatable thereon. One of opposed sides 107 of the idler wheel 
extends into the recess 105 to prevent lint or extraneous material from 
entering the interface region between the wheel 106 and shaft 103, thereby 
impairing the free-spinning ability of the idler wheel. The other one of 
opposed sides 108 of the idler wheel extends into a circular recess 109 
formed in an idler wheel extension member 110 fixed to the end of the 
shaft 103. While the housing 100 and extension member 110 are fixed, the 
idler wheel 106 rotates freely on shaft 103. 
A bearing 111 is preferably fixed in inner bore 112 of the idler wheel to 
facilitate rotation of the idler wheel on shaft 103. Metal disks 113a,113b 
are secured to or within opposed sides 107,108 of idler wheel 106. The 
metal disks should be made of non-magnetic materials such as aluminum, 
magnesium, stainless steel, or brass, although aluminum is preferred 
because of its low density, for reasons explained below, and low material 
cost. A ceramic coated, all metal idler wheel can also serve the same 
purpose. 
While the idler wheel 106 is typically plastic, a high hardness (e.g., 
ceramic) ring 114 is formed at the bottom of the notch in the idler wheel 
to prevent destruction by abrasion of the wheel due to contact with the 
yarn passing over the wheel. The wheel 106 is frictionally driven by the 
yarn 44 (FIG. 3) passing over it. 
A plurality of magnets 115 are arranged on opposite sides of the idler 
wheel in housing 100 and extension member 110. FIG. 7, a side view of 
housing 100 without idler wheel 106 and extension member 110, shows that 
the magnets are preferably arranged along concentric circles in housing 
100 (and preferably also in extension member 110). It is preferred that 
the magnets in housing 100 align with the magnets in extension member 110, 
and that the N-S orientation of opposed magnets in the housing and 
extension member be in the attraction mode, as shown in FIG. 6. Although 
any number of magnets can be used in any number of arrangements, the 
magnets 115 in each of housing 100 and extension member 110 should be 
spaced from each other to prevent cancellation of the magnetic fields from 
magnet to magnet. A preferable material for such magnets is an Nd-Fe-B 
alloy. 
The magnets 115 operate to produce magnetic eddy currents through the metal 
disks 113a,113b during rotation of idler wheel 106. The magnetic eddy 
currents are very weak or non-existent during initial start-up rotation of 
idler wheel 106, so that the idler wheel inertia at start-up of rotation 
is very low, and thus the idler wheel initially spins very freely. When 
idler wheel 106 is rotating at normal operating speed, the magnetic eddy 
currents are very strong. Aluminum is preferred for the metal disks 
113a,113b, because the density of other non-magnetic materials, e.g., 
gold, would create more moving inertial force or momentum of the idler 
wheel 106 than possible for the eddy currents to instantaneously 
decelerate. The idler wheel should not contain any ferrous or otherwise 
magnetic materials (such as screws) because such materials may cause undue 
additional continuous or pulsed magnetic drag. 
A circuit board 120 is mounted in the recessed bottom of the transparent 
housing 100 as shown in FIG. 6. The circuit board includes a 
photomicrosensor 121, which is a combined IR phototransistor and IR LED. 
Photomicrosensors of this type are sold by Omron, under product 
designation number EE-SMR3-1. The photomicrosensor emits an IR beam from 
the IR LED which is reflected from a pattern 116 (FIG. 8) formed on the 
side 107 or disk 113a of idler wheel 106 as rotation of wheel 106 passes 
the pattern segments through the IR beam. It is important that the pattern 
formed on the side of the idler wheel be perfectly centered around the 
axis of the wheel to ensure accurate detection of wheel speed. 
Instead of sensing a pattern provided on the idler wheel 106, the 
photomicrosensor can also detect stainless steel, aluminum or other 
non-magnetic material mounting bolts 116a used to mount the metal disk 
113a on the side 107 of the idler wheel 106. The reflected IR beam is 
detected by the IR phototransistor to create a voltage signal. The 
phototransistor generates voltage proportional to the amount of detected 
IR light reflected from pattern 116. The voltage signal and voltage 
frequency are processed by the microprocessor 310 to derive an average 
rotational speed of the idler wheel 106 and thus a linear speed of yarn 
passing thereover. 
In the event of yarn breakage, idler wheel 106 is no longer positively 
driven by yarn. Immediately after yarn breakage, the strong magnetic eddy 
currents induced in the metal disks 113a,113b by the magnets 115 act as a 
brake, causing substantially instantaneous reduction in rotational speed 
of idler wheel 106. The faster the rotational speed just before yarn 
breakage, the greater the braking power immediately after yarn breakage. 
In contrast, slower wheel speeds result in lower braking power by not 
generating as strong magnetic eddy currents. The microprocessor will 
detect, via the photomicrosensor 121, the instantaneous decrease in 
rotational speed of idler wheel 106 and cause the entire system to shut 
down, as explained later herein. 
Also mounted on the circuit board is an alarm LED 122 which is illuminated 
when yarn breakage occurs and there is an accompanying decrease in speed 
detected by the photomicrosensor 121. The prism-shaped outer surface 101 
of the housing 100 distributes the light emitted by the alarm LED 122 in 
several directions for easy visual detection by a human operator from 
multiple viewpoints. 
The circuit board also includes a connector 123 located in the recessed 
bottom 102 of the housing 100, for electrically connecting the sensor to 
the microprocessor 310 provided on each spindle. The connector 123 is 
protected by the walls of the housing 100 which define the recessed bottom 
102 of the housing 100. 
The housing 100 may be made from transparent injection molded or cast 
plastic (e.g., polycarbonate, general purpose polystyrene, acrylic, 
K-resin (a clear/highly crystalline polymer with high impact resistance 
produced by Phillips Chemicals, Co., Pasadena, Tex.), polyurethane or 
epoxy), and is thus very inexpensive. The circuitry is also very 
inexpensive in that only a commercially available photomicrosensor, LED 
and connector are required to build the sensor. Moreover, the idler wheel 
106 may be a standard off-the-shelf item. Accordingly, a very sensitive 
motion and presence sensor can be provided at very low cost. 
FIG. 9 shows another embodiment of the sensor of the present invention, 
wherein baffle grooves 117 are provided in the housing 100 and extension 
member 110, and mating baffles 118 are provided on the idler wheel 106. 
While the baffles do not inhibit free rotation of the idler wheel 106, 
they do assist in preventing lint from entering the bearing 111 of the 
idler wheel. By preventing lint from contacting the bearing 111, the life 
and reliability of the sensor is prolonged by assuring continuous free 
rotation of the idler wheel 106. 
FIGS. 10A and 10B show yet another embodiment of the yarn sensor of the 
present invention which incorporates the baffle design of FIG. 9, but uses 
a slightly different sensing mechanism. Like numerals represent like 
elements in FIGS. 8-10B. 
The sensor in FIG. 10A makes use of teeth or holes 127 formed in baffle 118 
(FIG. 10B), and an infrared LED 124 and a phototransistor 125 to detect 
speed of the idler wheel via a direct transmit/receive technique. The 
teeth or holes 127 interrupt the light transmitted from infrared LED 124 
and detected by phototransistor 125. A signal is thus generated by the 
phototransistor representative of the rotational speed of the idler wheel 
106 in the same manner as the sensor of FIGS. 8-9. The LED and 
phototransistor could also be arranged on opposite sides of the wheel 106 
to interact with a pattern of holes formed through the sidewall of the 
wheel 106. 
In the sensor shown in FIGS. 10A and 10B, a contact spring 126 provides 
electrical communication between the circuit board 120 and power supply 
rails 128. The power supply rails are slightly different from the 
connector 123 of FIG. 6, in that the rails 128 (four in total) enable (if 
desired) direct two-way communication to individual sensors along a 
central serial data binary bus (not shown), and also supply power to drive 
the individual sensor circuitry. This bus can simultaneously service a 
plurality of sensors at the same time along only four wires. This can be 
achieved at a very low cost by using a set of only four bus rails that run 
the full length of the machine line. This system is also suitable for 
installation on other textile machinery, including tufting machines, 
warping machines, and ring spinning machines. Direct two way communication 
with an individual yarn sensor can allow various information to be 
obtained and digested by a computer. The entire machine or individual 
spindle data can include runability efficiency, total run time, total down 
time and number of end breaks. Industrial engineering data is beneficial 
for fine tuning textile machinery for greater throughput productivity. 
Inexpensive two-way communication can enable the use of devices to stop 
off-quality product from being produced by shutting down material feed or 
knocking the end down (e.g., on a ring spinning frame) and allowing the 
waste to run into the vacuum exhaust conduit 31. This management tool can 
eliminate off-quality product, reduce waste, and improve machine 
runability and, hence, profitability. 
Preferably, the light emitted from the IR LED in the photomicrosensor 121 
is electronically (transistor switching on/off) pulsed to avoid detection 
of spurious/background light by the IR phototransistor. By pulsing the IR 
transmission at a specific frequency and pulsing the IR reception at the 
same frequency, extraneous light can be filtered out since it is not 
pulsed in sync with the receiver. The phototransistor can also include an 
optical filter to remove, and thus avoid detection of, extraneous IR 
light, such as fluorescent lighting and sunlight. 
Drafting Assembly 
FIG. 11 shows in cross-section the improved drafting assembly 42 of the 
present invention. While a four-roller drafting system is shown, three or 
five-roller systems can also be used. The assembly has a main body frame 
200 including a mounting bracket 201 designed to hold a roller assembly 
220, a thread-up device assembly 240, draft zone clearers 260 and a front 
roll wrap sensor 280. 
i) Roller Assembly 
The roller assembly 220 is designed to transport staple sliver S from the 
supply container 28 to the air jet spinner nozzle 12. The roller assembly 
220 includes opposed rear rollers 221, opposed intermediate rollers 222, 
opposed apron rollers 223, and opposed front rollers 224, all of which can 
come standard on a Murata MJS machine. Each set of opposed rollers forms a 
nip through which the sliver S passes. The apron rollers 223 stretch and 
orient the sliver and the front rollers 224 are rotated at a faster speed 
than the rear rollers 221 and apron rollers 223 to draw the sliver at a 
desired ratio as it passes through the roller assembly 220. Preferably the 
upper rollers closest to the mounting bracket 201 are rubber and the 
bottom rollers are metal. A tensor bar 225 (with height adjustment bracket 
225a) is provided in the bottom apron roller 223 to regulate the tension 
of the bottom apron and set the height of the apron nipping action. 
ii) Draft Zone Clearers 
The advantageous draft zone clearers 260 of the present invention are 
arranged on the mounting bracket 201 above and between the upper 
intermediate roller 222 and upper apron roller 223, and above and between 
the upper intermediate roller 222 and upper rear roller 221. Each clearer 
260 resembles a paddle wheel and is substantially star shaped, e.g., six 
vaned, in cross section. The clearers are each driven by a dedicated 
electric motor 261 mounted directly on the mounting bracket 201. The 
clearers 260 can be rotated in the same or opposite direction as the 
rotation direction of the upper rollers. The clearers contact the upper 
rollers to remove lint, dust, stray sliver, or other undesirable material 
which is then collected and discarded through the vacuum exhaust conduit 
31 (see FIG. 3). The clearers can be made from any material that is soft, 
flexible and durable, e.g., polyurethane, and preferably have a hollow or 
solid, rigid metal shaft for attaching the clearer to the shaft of the 
dedicated motor. 
During operation it is preferred that the clearer motors are off whenever 
the roller assembly is off. Also, it is preferred that the clearer motors 
are cycled on and off to prevent an in-sync condition between the apron 
and any roller. This cycling insures that the clearer contacts all 
segments of the upper apron and upper rollers. The cycling also extends 
the life of the motor and clearer. 
iii) Front Roll Wrap Sensor The front roll wrap sensor 280 is located on 
the mounting bracket 201 opposed to and above the upper front roller 224. 
The sensor 280 includes a photomicrosensor to detect the occurrence of 
roll wrap, that is, yarn undesirably wrapped around the upper front roller 
224. The photomicrosensor can be the same as that used in the elastomeric 
yarn sensor and includes an infrared light emitting diode which projects 
infrared light onto the upper front roller 224. The photomicrosensor also 
includes a phototransistor to detect infrared light reflected from the 
upper front roller 224. During initial operation of the drafting assembly 
42, the sensor 280 makes an initial detection of the reflectivity of the 
upper region of the upper front roller and that detection is represented 
by voltage generated in the phototransistor resulting from the IR light 
reflected from the upper front roller 224. If roll wrap occurs, yarn 
begins to wrap around the circumference of the upper front roller 224, and 
the presence of that roll wrap yarn increases the amount of light 
reflected back into the phototransistor of the photomicrosensor. The 
increased detected reflectance increases the voltage generated by the 
phototransistor, which in turn is monitored by the microprocessor 310 
(explained below). Any significant increase in reflectance (e.g., 
.gtoreq.10%) will shut-down the drafting assembly, as explained below 
herein. 
iv) Thread-UP Assembly 
The thread-up assembly 240 is shown in cross-section and greater detail in 
FIG. 12A. The device includes a main body 241 having a yarn delivery bore 
242 passing through the length thereof. The axis of the bore 242 should be 
arranged at an angle of 30.degree.-60.degree., preferably about 
50.degree., relative to the direction of sliver feed through the drafting 
assembly. See again FIG. 11. This arrangement will ensure fewer airjet 
nozzle chokes and roll wraps, and increases the chance for the spandex end 
to be entrained by the front roll nip point, and then the first airjet 
nozzle. 
First and second bores 243, 244 extend through a side surface 241a of the 
main body to communicate with the yarn delivery bore 242. Arranged in the 
first 243 and second 244 bores are pneumatic pistons 245, 246, 
respectively. Each of the pistons is biased by a spring 247 away from the 
yarn delivery bore 242. Each piston has an inner end 248 arranged adjacent 
the yarn delivery bore 242, and an outer plunger end 249 arranged 
proximate the side surface 241a of the main body. The inner end 248 of 
each piston mates with an inner surface portion 250 of the bore 242. 
A third bore 251 extends through the main body from the side surface 241a 
thereof to extend across and communicate with the yarn delivery bore 242. 
An air delivery tube 252 is arranged in the yarn delivery bore 242 and 
intersects a portion of the third bore 251. The upper end of the tube 252 
is fixed in the upper portion 242a of the yarn delivery bore 242. The 
lower end of the tube 252 extends into the lower portion 242b of the yarn 
delivery bore 242, and an annular gap 253 is defined therebetween (FIG. 
12B). The annular gap 253 ranges from about 0.002 inches to about 0.030 
inches in radial dimension "x", and preferably is about 0.005 inches in 
order to reduce air flow and maintain high thread-up aspiration below the 
tube 252. Instead of using such an annular gap, air can be supplied by 
adding an additional small diameter bore of approximately 0.032" at an 
angle of 15.degree. off the yarn delivery bore. 
A conduit block 254 is attached to the side surface 241a of the main body 
241, and provides air supply conduits 255,256 and 257 in communication 
with each of the first 243, second 244, and third 251 bores, respectively. 
Solenoid valves (not shown) are provided for each of the conduits 255, 256 
and 257 to control air flow therethrough. During operation of the 
thread-up device, air is supplied to the outer plunger ends 249 of each 
piston to actuate each piston selectively, such that the inner ends 248 
are forced into contact with the corresponding inner surfaces 250 of the 
bore 242. The upper piston 245 acts as a clamp for the yarn passing 
through the yarn delivery bore 242. The lower piston 246 acts as a 
clamp/cutter for the yarn, since continued rotation of the front rollers 
224 after the lower piston 246 is actuated will stretch and break the yarn 
44 below the lower piston 246. The air pressure supplied to each piston 
ranges from about 30 to 200 psi, and is preferably about 100 psi. 
The air supply conduit 257 provides air to the third bore 251 and into the 
yarn delivery bore 242 via the annular gap 253 defined between the lower 
end of the tube 252 and the lower portion 242b of the yarn delivery bore 
242. The air thus entering the bore 242 is laminar and concentrated at the 
periphery of the bore 242 such that a suction effect occurs in the bore 
242. This suction effect insures proper feeding of the yarn 44 material 
through eyelet 242c of the bore 242 and out extension pipe 258. The air 
pressure supplied to bore 251 ranges from about 20 to 120 psi, and 
preferably is about 50 psi. 
The spandex yarn finally travels through extension pipe 258 before merging 
with the drafted sliver. Although the extension pipe is shown as a 
cylindrical tube in FIG. 12A, the interior thereof preferably gradually 
tapers down from about 3/16" to about 1/8", allowing better front-to-back 
and side-to-side aiming of the fired spandex before redirection by the 
front roll. This slight taper results in minimum disruption of air flow 
while improving control of directing the spandex into the front roll. 
FIG. 13A shows an alternative embodiment of the thread-up assembly of the 
present invention. Wherever possible like reference numerals have been 
used to designate like structure in FIGS. 12A and 13A. 
The thread-up assembly of FIG. 13A includes a main body 241 having a square 
yarn cross-section delivery bore 242 passing through the length thereof. 
Use of a round cross-section bore 242 intersecting with a round 
cross-section bore 243 causes turbulence of the air passing through the 
bore 242. This turbulence can be reduced by using a square cross-section 
bore 242 in combination with the planar-shaped piston ends 248. First and 
second bores 243, 244 extend through a portion of the main body to 
communicate with the yarn delivery bore 242. Arranged in the first 243 and 
second 244 bores are pneumatic pistons 245, 246, respectively. Each of the 
pistons is biased by a spring 247 away from the yarn delivery bore 242. 
Each piston has an inner end 248 arranged in the yarn delivery bore 242 
and an outer plunger end 249 arranged within the bores 243, 244. FIG. 13B 
shows a top view of each piston 245, 246 as it interacts with side plate 
262, which cooperates with the main body 241 to define the square 
cross-section yarn delivery bore 242. The inner end 248 arranged in the 
yarn delivery bore includes two prongs 260 which ride within corresponding 
grooves 261 of the side plate 262. When each piston is in the fully 
retracted position, the prongs 260 define the side walls of the yarn 
delivery bore 242 at the location of each piston. That is, the square hole 
passing through each piston inner end 248 is roughly the same dimension as 
that of the square yarn delivery bore 242. Guide disks 263 are provided in 
each bore 243, 244, to guide the inner end 248 of each piston and to 
provide stop points for coil springs 247 provided in bores 243, 244. 
A third bore 251 extends through a portion of the main body 241 and 
communicates with the yarn delivery bore 242. An air orifice 264 extends 
from the end of the third bore 251 at an angle into the yarn delivery bore 
242. Air is delivered through the bore 251 and air orifice 264 to force 
the yarn 44 through the thread-up device. 
During operation, the upper 245 and lower 246 pistons function in the same 
way as the thread-up assembly of FIG. 12A, although in the thread-up 
assembly of FIG. 13A each piston, when actuated, closes the yarn delivery 
bore 242, thus clamping and clamping/cutting, respectively, the yarn 
passing through the yarn delivery bore 242. 
Arranged at the inlet end of the thread-up assembly shown in FIG. 13A is a 
ceramic idler wheel 265 on which the yarn rides as it enters the thread-up 
assembly. The wheel can also be arranged outside the body 241, as shown in 
FIG. 13E. The ceramic idler wheel 265 prevents erosive abrasion of the 
entrance to the yarn delivery bore 242, especially when feeding spandex 
through the thread-up assembly. The ceramic idler wheel is arranged to be 
freely rotatable, and preferably the bottom of the V defined by the 
sidewalls of the wheel is in substantial alignment with the central axis 
of the yarn delivery bore 242. 
FIG. 13A also shows that the presence of the yarn passing through the 
thread-up assembly can be detected within the assembly itself. 
Specifically, as shown in the exploded view of FIG. 13C, a laser diode 
module 266 is arranged in a bore 267 which communicates with the yarn 
delivery bore 242. The laser diode module includes a lens 266a, a laser 
diode 266b, a power rectifier 266c and a shell 266d. A photodetector 268 
is arranged in a bore 269 formed in the back of the thread-up assembly in 
communication with the yarn delivery bore 242. The photodetector 268 is 
mounted out of the laser diode generated lightwave beam. The axis 268a of 
the photodetector 268 preferably is arranged at an angle of 135.degree. 
with respect to the axis 266a of the laser diode 266, as shown in FIG. 
13D, in order to optimize the sensitivity of the photodetector 268. A 
laser anti-reflection cone 270 is employed on the opposite side of the 
yarn delivery bore 242 in alignment with the laser diode 266 to scatter 
any extraneous light energy emitted from the laser diode 266. In order to 
attenuate the signal-to-noise ratio for more reliable signal readings and 
analysis, light bandpass interference filters may be used in front of the 
photodetector 268 to shield extraneous light from reaching the 
photodetector, which extraneous light would otherwise skew or distort the 
true signal generated by the yarn passing through the thread-up assembly. 
The laser light may also be electronically pulsed or modulated in 
synchronization with the photodetector to filter additional unwanted 
light. 
As the yarn runs through the lightwave beam, light is reflected and/or 
refracted toward the photodetector 268 creating a proportional voltage 
based on the amount of redirected light, which is also directly 
proportional to the size of the yarn passing through the lightwave beam. 
With calibration, the speed and size of the yarn passing through the 
thread-up assembly may be determined. Calibration also may provide other 
important information when using yarns other than spandex, such as quality 
consistency (e.g., hairiness, evenness, defect levels, thick, thin, neps) 
of yarn material passing through the lightwave beam. 
As is the case with the yarn motion and presence sensor described above, 
the output from the photodetector 268 is monitored by the microprocessor 
to determine, among other things, the presence and/or speed of the yarn 
passing through the thread-up assembly. A prism-shaped LED alarm light 271 
is illuminated whenever the microprocessor fails to detect yarn 44 passing 
through the yarn delivery bore 242, much like the alarm LED in the yarn 
motion and presence sensor described earlier herein. 
Although any type of laser diode 266 can be employed in the present 
invention, a high intensity 1 to 5 milliwatt laser operating at 670 nm 
wavelength and a silicon phototransistor detector 268, has been used. 
Preferably the laser diode includes a convex plano lens to focus the 
lightwave beam into the yarn delivery bore. 
FIG. 13F shows an alternative embodiment of the thread-up device of FIG. 
13A, wherein the sensor of FIG. 6 is employed instead of laser sensor 266. 
Yarn Clearer Delay Cylinder 
In certain instances that will be explained below, it is necessary to 
physically move the core/wrap yarn out of registration with the yarn 
clearer sensor 3. The present invention employs yarn clearer delay 
cylinder 43 for this purpose. 
FIG. 14A is a top view showing one embodiment of the yarn clearer delay 
cylinder 43. The delay cylinder 43 is mounted on the front plate of each 
spindle as shown in FIG. 3. During normal operation, the final yarn 
product passes through head slot 3a of the yarn clearer sensor 3. The 
delay cylinder 43 serves to force the yarn out of head slot 3a, for 
reasons explained below. A waste suction duct 31a is provided for removing 
any defective yarn and other debris from the area of the sensor 3. 
The delay cylinder 43 includes a solenoid 43a having a plunger 43b attached 
to an end thereof. A first pin 43c attached to the plunger 43b assures 
axial alignment of the plunger during actuation of the solenoid 43a. A 
second pin 43d attached to the plunger forces the yarn product out of head 
slot 3a. The dotted lines in FIG. 14A show the plunger 43b in the 
activated position. 
FIG. 14B shows an alternative embodiment of the delay cylinder 43 of FIG. 
14A, wherein the plunger 43b is shaped like a triangle with a front edge 
43e rolled downwardly to provide a smooth surface for contacting the yarn 
product. 
FIG. 14C shows another embodiment of the delay cylinder 43 of FIG. 14B, 
wherein slots 43f and 43g, and set screws 43h and 43i facilitate 
side-to-side and back-to-front adjustment of the position of the plunger 
43b. 
FIG. 14D shows the delay cylinder 43 with the plunger 43b in the retracted 
position (solid lines) and the plunger 43 in the activated position 
(dotted lines). When the plunger 43b is in the activated position, the 
yarn product is forced out of head slot 3a beyond the sensor 3. It is 
important, when using capacitance-type sensors 3, to remove the core/wrap 
product from head slot 3a as well as the opening to head slot 3a, because 
the sensing region of such sensors tends to extend somewhat beyond the 
head slot 3a. 
Interfacing The Yarn Feed System With a Murata MJS Machine 
In developing and testing the yarn feed system of the present invention, a 
Murata MJS Model 801-9786-4 was used, although other models of Murata's 
MJS machine may be adapted to accept the yarn feed system of the present 
invention. The description hereinbelow is in the context of a Murata MJS 
Model 801-9786-4. 
FIG. 15 schematically shows the output configuration of the MJS unit 
control box 300 which is a standard feature on the MJS machine to control 
various operations of the machine. Each spindle of the MJS machine has its 
own unit control box 300. The unit control box 300 includes integrated 
circuit chips and jacks 301, to which connectors 302 of patch cords 303 
are connected, for controlling operation of the spindle in a known manner. 
For example, one of the jacks 301c, color coded blue, feeds signals to the 
solenoid (324, FIG. 17) of the spinning/sliver clutch (a standard 
component on the MJS), which controls the feed of sliver 3 to the drafting 
assembly 200. Room for a spare jack 301g, color coded black, is provided 
on the standard MJS unit control box 300. 
To seize control of operation of the spindle and incorporate the functions 
of the yarn feed system of the present invention, each spindle is provided 
with a second circuit board 310 in accordance with the present invention. 
FIG. 16 schematically shows the interfacing between the standard MJS unit 
control box 300 (with spare jack 301g added) and second circuit board 310. 
A pin connector 311 connected to the circuit board 310 has a first patch 
cord 312 extending therefrom to access the spare jack 301g on the unit 
control box 300. A second patch cord 313 extends from the pin connector 
311 and accesses the spinning clutch jack 301c of the unit control box 
300. A third patch cord 314 extends from the pin connector 311 and 
accesses the standard spinning clutch on the MJS. A relay ("Relay 3", FIG. 
17) is provided on the circuit board 310 to allow standard control of the 
spinning clutch by the unit control box 300 or to allow the second circuit 
board 310, particularly the microprocessor chip 320, to seize control of 
the spinning clutch of the MJS in accordance with the present invention. 
The spare jack 301g includes two pins (7A, 7B; FIG. 18B) for communicating, 
via patch cord 312, with two pin connections 322, 323 on the circuit board 
310 shown in FIG. 17. The two pins in jack 301g are connected by wires to 
existing wiring in the MJS unit control box 300 as shown in FIG. 18B. The 
block diagram in FIGS. 18A and 18B are from circuit board #881021A 
included in the unit control box 300 of the MJS Model 801-9786-4. 
In the block diagram of FIGS. 18A and 18B, plug numbers 1-6 correspond to 
the plugs color coded in FIG. 16 as green, clear, blue, yellow, gray and 
red, respectively (i.e., the order of plugs in FIG. 18 being opposite that 
shown in FIG. 17). Plug number 7 in FIG. 18B corresponds to the black 
color coded plug in FIG. 16. FIG. 18A corresponds to the standard unit 
control box on the Murata MJS, and FIG. 18B shows the same unit control 
box 300 modified to interface with the yarn feed system of the present 
invention. 
Plug number 3, controls the spinning/sliver clutch of the MJS. In 
accordance with the present invention, that plug is removed and replaced 
with the plug extending from patch cord 313 shown in FIG. 16. FIG. 18B 
shows that the second wire 3D of the number 3 plug is connected to the D 
wire of the number 7 plug. The C wire of plug number 7 is connected to the 
terminal on the standard Murata circuit board to which the 3D wire of the 
number 3 plug previously was connected. The 7A and 7B wires of the number 
7 plug are connected to the components labeled D.sub.9 and D.sub.3, 
respectively, on the standard Murata circuit board. As explained above, 
the 7A and 7B wires are connected to pins 322 and 323 shown in FIG. 17. 
The block diagram in FIG. 18B shows the extent to which the circuit board 
of the existing unit control box 300 on the Murata MJS is interfaced with 
circuit board 310 in accordance with the present invention. 
The remaining pin-outs of the control circuit board 310 will be explained 
hereinbelow. 
Operation 
By way of example, the exemplary circuit diagram shown in FIG. 17 and the 
production of spandex core/synthetic blend wrap yarn will now be explained 
in the context of a Murata MJS Model 801-9786-4 modified to include the 
yarn feed system of the present invention (using the package drive 
assembly of FIGS. 4 and 5A, the sensor of FIG. 6, and the thread-up 
assembly of FIG. 12A. 
FIGS. 19A-D show a detailed flow diagram of the operational control program 
stored in the microprocessor chip 320 on the second circuit board 310. The 
operation and control of the MJS as modified in accordance with the 
present invention will be explained below in the context of four 
sequences: Initial Thread-up; Automatic Threading; Breakage; and 
Shut-Down, all with reference to FIGS. 19A-D, respectively. Any 
operator-assisted steps or explanatory notes not part of the program are 
shown in dotted lines in FIGS. 19A-D. 
Initial Thread-up Sequence--FIG. 19A 
During initial threading of a new spandex yarn package, or if the yarn 
breaks above the thread-up device 240, the package 50 is positioned on the 
package tube holder 56 and the outside peripheral surface of the package 
contacts the package drive roller 60. The package tube holder shaft 55 can 
be moved up and down through oblong slot 54 formed in front face 51a of 
mounting plate 51. The slide block 53 moves up and down in the slide block 
channel 52 to maintain the rotating axis of the package 50 parallel to the 
rotating axis of the package drive roller 60. As yarn is drawn off package 
50, gravitational force and the biasing force of the coil spring 59 cause 
the package 50 to maintain constant contact with the drive roller 60. 
During initial thread-up, as shown in FIG. 19A, the spandex yarn sensor 41 
is disabled and the solenoid 324 of the spinning clutch is disengaged to 
stop the feed of sliver to the drafting assembly. A human operator then 
meters several inches of spandex yarn from the package 50 and presses the 
set-up button 61a (shown in FIG. 3) to initiate the Initial Thread-up 
Sequence. At this time the front roll wrap sensor 280 takes an initial 
reading from the upper surface of the upper front roll 224 and that 
reading is stored in the microprocessor chip 320. 
The drive roll motor 61 is then disabled by removing the current supplied 
thereto. Since the drive roll motor is a so-called stepper motor, low 
levels of current can be applied thereto to prevent the shaft of the motor 
from rotating due to external rotational forces applied to the shaft. When 
current is not supplied to the motor, the shaft can be turned freely, and 
thus the human operator can rotate the spandex package accordingly. 
Pressing the set-up button also causes the top clamp 245 and the lower 
clamp/cutter 246 to be released by operation of their respective solenoid 
valves provided in conduits 255 and 256, and also causes air to be 
supplied to the yarn delivery bore 242 of the thread-up device 240 by 
operation of the solenoid valve in conduit 257. There is then a delay of 
about 4 seconds during which time the human operator must manually feed 
the end of the spandex yarn into eyelet 242c of thread-up device 240. 
After the 4 second delay, the top clamp 245 is activated and simultaneously 
the air supplied to the yarn delivery bore 242 is terminated. The 
microprocessor then again determines whether the set-up button 6la is 
pressed. If it is pressed, this means that the human operator was unable 
to successfully manually feed the end of the spandex yarn through the 
thread-up device 240 and the set-up sequence begins again as shown in FIG. 
19A. 
If the set-up button is not pressed, but instead the human operator was 
successful in feeding the yarn through the thread-up device 240 and 
pressed the red flag (a standard switching mechanism in the Murata MJS) to 
signal the knotter that the spindle is ready for automatic threading 
(discussed below), the microprocessor then checks whether the microswitch 
(MS, FIG. 3) on the spindle has been activated by the knotter. The knotter 
sequence (standard on the MJS) is also shown in FIG. 19A. If the 
microswitch has not been activated, the computer program loops or recycles 
as shown in FIG. 19A until the microswitch is activated by the knotter. In 
certain instances where the operator is manually doffing a full package of 
core/wrap yarn, the mechanical microswitch may be activated manually by 
the operator. 
At this stage, top clamp 245 of thread-up device 240 is holding the spandex 
yarn end in yarn delivery bore 242, so that the spandex yarn can be 
introduced into the drafting assembly during the Automatic Threading 
Sequence. The spandex yarn may or may not be visibly extending from the 
exit surface of the thread-up device 240. The human operator should index 
the creel package in reverse to remove any slack from the spandex yarn 
end. 
Automatic Threading Sequence--FIG. 19B 
Once the knotter is situated at the spindle and activates the microswitch 
on the spindle, the Automatic Threading Sequence begins. The 
microprocessor enables the drive roll motor (via "Enable 61" in FIG. 17) 
by providing enough current thereto actively to prevent free rotation of 
the motor shaft, but insufficient current to actually rotate the motor 
shaft. Then, at the same time, the upper clamp 245 is released (by 
operation of the solenoid valve in conduit 255), ramping current is 
supplied to the drive roll motor 61, and air is supplied to yarn delivery 
bore 242 (by operation of the solenoid valve in conduit 257) via the third 
bore 251 and air supply conduit 257 provided in conduit block 254. 
The microprocessor then turns on the electronic yarn clearer bypass, which 
is simply an electronic relay switch (Relay 1 in FIG. 17) that prevents 
output from the yarn clearer sensor 3 (e.g., a Seletex.RTM. sensor) from 
being detected by the microprocessor. Allowing the yarn clearer sensor 3 
to be active during initial production of the core/wrap yarn could cause a 
voltage spike in the yarn clearer due to the increased size of the yarn in 
a relaxed state due to lack of tension. It could take the yarn clearer up 
to 15 seconds to recover from the voltage spike, during which time the 
spindle would not function. 
After about a 2 second delay, the air supply to the thread delivery bore 
242 is terminated. At this time, since the front rollers (and apron 
rollers) of the drafting assembly are not disabled by the spinning clutch, 
the spandex yarn has been fed through the air jet spinning nozzle 12. 
After the air supply to the thread delivery bore 242 is terminated, there 
is a 0.2 second delay to make sure all air is out of the thread-up device 
240, and then the solenoid 324 of the spinning (sliver) clutch is engaged 
to feed sliver to nozzle 12. By this time the knotter has positioned the 
suction hose 24 at the exit of the air jet spinning nozzle 12, and 
drafting assembly 11, in conjunction with suction hose 24 and the spandex 
yarn already fed through the air jet spinning nozzle, assist in feeding 
the drafted sliver synthetic blend yarn through the air jet spinning 
nozzle 12. The drafted synthetic blend fibers are wrapped around the 
spandex yarn core in the air jet spinning nozzle 12. 
After the sliver clutch is engaged, as shown by box 413 in FIG. 19B, there 
is a 3 second delay, and then the microprocessor calculates the rotation 
speed of the idler wheel 106 in the spandex yarn sensor 41 using signals 
produced by the photomicrosensor, as explained above. This initial 
rotational speed of the idler wheel in the spandex yarn sensor is used as 
a threshold value against which future rotational speeds will be compared 
to detect breakage of the spandex yarn above the thread-up device 240. 
The microprocessor then determines whether the front roll wrap sensor 280 
is experiencing an alarm condition (i.e., whether spandex and/or synthetic 
blend yarn are wrapping around the front roll 224 of the drafting 
assembly). If so, then the microprocessor begins the Breakage Sequence as 
explained later herein. 
If the roll wrap sensor is not experiencing an alarm condition, the 
microprocessor then determines whether the spandex yarn sensor 41 is 
experiencing an alarm condition. That is, the microprocessor determines 
whether there is breakage above the thread-up device 240. If no alarm 
condition is sensed in the spandex yarn sensor, the microprocessor then 
proceeds to activate the yarn clearer delay cylinder 43 (by operation of 
solenoid 43 shown in FIG. 17). As explained above, the delay cylinder 43 
is a solenoid activated mechanical plunger which extends outwardly from 
the front of the spindle to push the core/wrap yarn in and out of yarn 
clearer sensor 3. Delay cylinder 43 prevents the initially produced 
core/wrap yarn from entering the yarn clearer sensor head, because the 
quality of this yarn is not yet acceptable. An erroneous quality reading 
would result if the initial core/wrap yarn was detected by the yarn 
clearer sensor 3. 
After activating the yarn clearer delay cylinder 43, there is then about a 
7 second delay during which the knotting cycle is completed and all kinks 
are pulled out of the core/wrap yarn product being produced by the 
machine. That is, as in the conventional MJS machine, the suction hose 24 
of the knotter 7, in conjunction with the suction pipe 25 of the splicer 
27, tie the core/wrap yarn exiting the nozzle to the core/wrap yarn 
already wound on the take-up roll 22. The clearer delay cylinder 43 is 
then retracted so that the core/wrap yarn is allowed to pass through the 
head of the yarn clearer sensor 3, and then, after a 3.5 second delay, the 
yarn clearer electronic bypass is released (by operation of Relay 1). At 
this time the modified MJS is now producing high quality core/wrap yarn 
and the microprocessor now simply waits until an alarm condition is 
detected by one (or more) of the spandex yarn sensor, front roll wrap 
sensor or by monitoring the microswitch (MS). 
Breakage Sequence--FIG. 19C 
If spandex and/or synthetic blend yarn begins to wrap around the front roll 
224 of the drafting assembly, the front roll sensor 280 sends an alarm 
signal to the microprocessor. The microprocessor then begins the Breakage 
Sequence shown in FIG. 19C. Likewise, if the yarn clear sensor 3 detects 
excessively slubbed, thick, or thin core/wrap yarn, it releases the 
spinning lever (standard on MJS), which in turn causes the microswitch 
(MS) to be released. The microprocessor would also begin the Breakage 
Sequence at this point. 
FIG. 19C shows that the Breakage Sequence begins by disabling all alarms, 
turning off the electronic yarn clearer sensor (e.g., a Seletex.RTM. 
sensor) bypass, and activating the clearer delay cylinder 43. Then the 
lower clamp/cutter 246 is activated to cut the supply of spandex yarn to 
the drafting assembly, and at the same time the sliver clutch is 
disengaged to stop the flow of sliver to the drafting assembly. Continued 
rotation of the front rollers 224 breaks the spandex yarn below the lower 
clamp/cutter 246 and conveys any remnant sliver out of the drafting 
assembly. After a 160 millisecond delay, the upper clamp 245 is activated 
and a delay value (X) (FIG. 17) is retrieved from memory to determine the 
deceleration ramp or rate of deceleration of the drive roller motor 61. 
The delay value (X) is programmed by the operator based on how much draw 
(extension) is desired to be maintained in the spandex yarn between the 
spandex package 50 and the thread-up device 240. The amount of draw 
produced by the rollers in the drafting assembly of the MJS is 
communicated to the microprocessor via the "Draw" pin-out shown in FIG. 
17. The delay value (X) is communicated to the drive roller motor, which 
begins deceleration. The upper clamp 245 is then deactivated and the 
driving current supplied to the drive roll motor is terminated (via 
"Enable 61", FIG. 17). Again, a nominal current is supplied to the drive 
roll motor to prevent free rotation of the spandex package 50. 
After the upper clamp 245 is deactivated and the drive roll motor is 
stopped, there is a 0.2 second delay to allow the creel package to index 
to release tension in the spandex 44 between the activated lower 
clamp/cutter 246 and the package 50, and then the upper clamp 245 is again 
activated to hold the spandex in place. After another 0.2 second delay, 
the lower clamp/cutter 246 is deactivated, the yarn clearer delay cylinder 
43 is turned off, and the drive roll motor 61 is disabled, all occurring 
simultaneously, as shown in FIG. 19C. The program then proceeds to the 
"check set-up" command as shown by box 414 in FIG. 19A. The machine is now 
again ready to start the Automatic Threading Sequence. 
Shutdown Sequence--FIG. 19D 
If the microprocessor does not detect any alarm in the front roll sensor 
280, it then determines whether the microswitch is off due to an abnormal 
condition detected by the yarn clearer sensor 3 (discussed above). If the 
microswitch is off, then the microprocessor accesses the Breakage Sequence 
as explained above. If the microswitch is on, the microprocessor then 
determines whether there is an alarm condition in the spandex yarn sensor 
41. If no alarm condition exists, the microprocessor simply continues 
looping or cycling in the monitoring loop as shown in FIG. 19B. If there 
is an alarm condition in the spandex yarn sensor 41, this means that the 
spandex yarn has broken above the thread-up device 240. The microprocessor 
will then proceed to the Shutdown Sequence of FIG. 19D and shut off the 
electronic yarn clearer sensor bypass, activate the yarn clearer delay 
cylinder (to push the core/wrap yarn out of the yarn clearer sensor head 
to avoid an erroneous quality reading), and immediately stop the drive 
roll motor 61. After about a 2 second delay, the yarn clearer delay 
cylinder is released, the drive roll motor is disabled (i.e., all current 
to the motor is terminated via the "shut-off 61"pin-out shown in FIG. 17), 
and all alarms are disabled. 
After the human operator clears any debris from the drafting assembly, the 
system is now ready to proceed to the Initial Thread-up Sequence explained 
earlier herein. 
The Core/Wrap Yarn 
Prior to the present invention, there was no commercially viable system for 
producing elastomeric core/wrap yarn using air jet spinning techniques. 
The system of the present invention produces a superior quality 
elastomeric core/wrap yarn using air jet spinning techniques. 
FIG. 20 is a partially schematic, partially cut-away illustration of the 
core/wrap yarn 500 of the present invention. The elastomeric core yarn 501 
typically is a coalesced multifilament spandex yarn such as that available 
from DuPont under the trademark Lycra.RTM., although it may be a single 
filament or multifilament highly elastic yarn, as desired. The elastomeric 
core yarn can be white or clear, depending upon the desired end use of the 
core/wrap yarn. The wrap 502 comprises staple fibers of synthetic or 
synthetic-cotton blend materials. 
This core/wrap yarn is distinguishable from elastomeric core/wrap yarns 
formed by former methods such as ring spinning, in that the core/wrap yarn 
of the present invention includes wrapper fibers twisted around the 
exterior of the bundle of wrapper fibers which encase the core, whereas 
ring spun core/wrap yarns do not include such twisted outer wrapper 
fibers. Additionally, there is no residual twist in the present core/wrap 
yarn, as is present in ring spun core/wrap yarns. 
The system of the present invention all but renders obsolete the prior 
machines for making elastomeric core/wrap yarns, in that the present 
system allows a 60 spindle MJS machine to perform the work of 600-900 
roving fed ring spinning machines. Additionally, the core/wrap yarn of the 
present invention is extraordinarily free of defects, such as splicing 
knots due to breaks, over lengths of at least 15,000 yards. In fact, 
entire doff packages of about 32,000 yards of defect-free core/wrap yarn 
have been produced on a regular basis. 
While the present invention has been described above in detail, it will be 
appreciated by those skilled in the art that various changes and 
modifications could be made thereto without departing from the scope and 
spirit thereof as defined in the attached claims. For example, the 
invention has been explained in the context of a Murata MJS machine, but 
could be adapted for use on other jet spinning machines.