Method and device for forming a thread joint

A method of forming a thread joint in an open-end spinning machine having a sliver drawing-in device for drawing in a sliver and feeding it to a fiber loosening device from which it is guided by a fiber guiding device to a fiber accumulator at which the fibers are accumulated, disentangled, imparted with a rotary motion, and thereafter engaged with an open end of a thread, and a take-up device for drawing the thread out of the fiber accumulator includes for the purpose of joining a joint, bringing a thread end which is fed back into the fiber accumulator into contact with a quantity of fibers to be joined which have been previously fed into the fiber accumulator, continuously withdrawing the thread out of the fiber accumulator and continuously feeding fibers into the accumulator, continuously measuring the quality of the joints and automatically controlling, in accordance with the quality, the quantity of fibers being joined.

The invention relates to a method and a device for forming a thread joint 
or piecing a thread, more particularly, in an open-end spinning unit 
having a sliver drawing-in device for drawing in a sliver and feeding it 
to a fiber loosening device from which it is guided by a fiber guiding 
device to a fiber accumulator at which the fibers are accumulated, 
disentangled, imparted with a rotary motion, and thereafter engaged with 
an open end of a thread, and a take-up device for drawing the thread out 
of the fiber accumulator. 
In this regard, the type of fiber accumulator for use in the invention of 
the instant application is of secondary importance. As is generally known, 
there are many differently constructed fiber accumulators, and there are 
correspondingly different ways for a fiber accumulator to impart a rotary 
motion of the fibers. If the fiber accumulator is, for example, 
constructed as a rotor and the latter has a fiber collecting groove, the 
fibers then lay themselves out lengthwise in the fiber collecting groove 
and encircle the rotary axis of the fiber accumulator. In other fiber 
accumulators, the fibers are, for example, imparted with rotary motion 
about the longitudinal axes thereof. 
Especially in the case of an open-ended rotary spinning machines, it is of 
importance for the quality of the joint, as to what peripheral speed the 
fiber accumulator in fact rotates at, during the instant in which the fed 
back thread end contacts the quantity of fibers to be joined which are 
present in the fiber accumulator, and as to how great the quantity of 
fibers to be joined actually is during that instant. 
Various possibilities exist for determing beforehand the quantity of fibers 
to be joined, for example, in accordance with the draft selected for the 
spinning operation or process or in accordance with other criteria. 
In this regard, it is already difficult to attain a good quality of the 
joint from the start and it is at least just as difficult, for an 
insufficient joint quality, to change the correct influencing parameters 
by the correct amount in order finally to achieve good joints. In this 
regard, deviations from spinning unit to spinning unit of one and the same 
machine and deviations over time must be taken into account so that one 
must continuously measure and correct if one wishes to maintain the 
quality of the joints lastingly at high level. 
It is accordingly an object of the invention to provide a method and device 
for forming good joints rapidly even under undesirable conditions and then 
to maintain them at a high quality level so that the number of 
unsuccessful joining attempts are diminished. 
With the foregoing and other objects in view, there is provided, in 
accordance with one aspect of the invention, a method of forming a thread 
joint in an open-end spinning machine having a sliver drawing-in device 
for drawing in a sliver and feeding it to a fiber loosening device from 
which it is guided by a fiber guiding device to a fiber accumulator at 
which the fibers are accumulated, disentangled, imparted with a rotary 
motion, and thereafter engaged with an open end of a thread, and a take-up 
device for drawing the thread out of the fiber accumulator, which 
comprises, for the purpose of forming a joint, bringing a thread end which 
is fed back into the fiber accumulator into contact with a quantity of 
fibers to be joined which have been previously fed into the fiber 
accumulator, continuously withdrawing the thread out of the fiber 
accumulator and continuously feeding fibers into the accumulator, 
continuously measuring the quality of the joints and automatically 
controlling, in accordance with the quality, the quantity of fibers being 
joined. The quality of the joint is measured especially with respect to 
mass per unit length and/or thick location and/or thin location and/or 
yarn number. 
In accordance with another mode of the invention, the method includes the 
quality of the joints is continuously measured by comparing a number of 
too-thick joints measured in a given time period with a number of too-thin 
joints measured in the same time period, reducing the quantity of fibers 
to be joined when a preponderance of the too-thick joints are measured, 
and increasing the quantity of fibers to be joined when a preponderance of 
the too-thin joints are measured, and maintaining unchanged the quantity 
of fibers to be joined when, within a prescribed tolerance, a 
substantially equal number of too-thin and too-thick joints are measured 
in the given time period. From case to case, time periods of varying 
length, predetermined time intervals or time periods resulting from 
predetermined time intervals may be involved. 
This particular mode of the method is especially worthy of recommendation 
wherein a thick location and also a thin location always initiate a 
cleaning process, which means, that the joint is removed each time and a 
new joining operation is released with the object of finally attaining a 
good joint even after two to three joining attempts. The method according 
to the invention thus reduces the number of unsuccessful joining attempts 
to a minimum value. 
Because the joint quality depends upon how many fibers are actually at the 
joining location and whether exceedingly longer or exceedingly shorter 
fibers are involved, correction oscillations could result which are 
avoided when, in accordance with a further mode of the invention there is 
provided a method which includes automatically performing a continuous 
addition of joints exceeding the quality tolerance, thick joints having a 
positive value and thin joints having a negative value and, when a 
prescribed difference is exceeded, automatically changing the quantity of 
fibers to be joined, interrupting the continuous addition and newly 
beginning the continuous addition once again. So long as the thin 
locations and thick locations maintain the weight, it is assumed that the 
number of the neither too-thin nor too-thick joints is a maximum. No 
change then occurs in the quantity of fibers being joined. If, for 
example, after four or five thin locations, a like number of thick 
locations follows, the quantity of fibers being joined is not changed. If, 
however, for example, six thick locations follow five thin locations, the 
prescribed difference can already be exceeded. Consequently, a correction 
takes place, for example, automatically by a given amount. 
In accordance with an added mode of the invention there is provided a 
method which includes measuring the corrected quantity of fibers provided 
for the respective reduction and increase in the quantity of fibers to be 
joined, automatically, inversely proportional to the number of joints 
exceeding the quality tolerance and included in the addition during at 
least one of the continous and preceding addition processes. In this mode 
of the inventive method, a suitably large correction is caused from the 
start. If, for example, thin locations and thick locations maintain the 
weight for a long time and then first exceed the prescribed difference, 
this means that only a quite small correction should be undertaken. If the 
prescribed difference has been reached very rapidly, on the other hand, 
then in the extreme case if, for example, only thin locations or thick 
locations occur, an especially great correction step is taken in 
accordance with the invention. In this manner, qualitatively good joints 
are again rapidly attained and few faulty joints are formed. 
Instead of only including those joints in the addition which occur as thin 
locations or thick locations, in accordance with an additional mode of the 
method of the invention, which includes measuring corrected quantity of 
fibers provided for the respective reduction and increase in the quantity 
of fibers to be joined, automatically inversely proportional to the number 
of all of the joints measured during an addition process which has just 
ended. It could indeed be that the predominant majority of all the joints 
is already qualitatively good and that then, however, suddenly stray 
faulty joints occur, whereupon, if no correction is made, good joints 
would probably come on again. Because, in such a case, however, the amount 
of correction is very small, occasional faulty joints cannot cause any 
undue correction oscillations. 
In lieu thereof, in accordance with yet another mode of the method of the 
invention, which includes measuring the corrected quantity of fibers 
provided for the respective reduction and increase in the quantity of 
fibers to be joined, automatically proportional to a mean thread signal of 
the joints measured during an addition process which has just ended. 
Independently of the spinning conditions and of the employed fiber 
material, it may happen that a very uniform yarn is spun and, accordingly, 
also no great deviations in quality of the joints will occur. In this 
case, it may be more desirable if, in accordance with yet a further mode 
of the invention, which includes maintaining a prescribed corrected 
quantity of fibers within tolerance limits with each change of the 
quantity of fibers to be joined. This means that the respective corrected 
quantity of fibers is so measured that, because of its size, it has not 
yet started any control oscillations and that it is, nevertheless, large 
enough to attain adequate correction in one or more correction steps. 
In accordance with still another mode according to the invention, the 
method which includes measuring the quality of the joints by determining 
the mass per unit length for each joint, forming a mean value from the 
measured values of a plurality of the joints and comparing it with the 
mass per unit length of the thread, and changing the quantity of fibers to 
be joined in proportion with the deviation in the mass. 
In this mode of the method, the quantity of fibers to be joined is varied 
until the joint has the desired quality. With changes in the thread mass 
per unit length, the joints also change proportionally due to the 
correction. 
In accordance with a further mode of the invention, the method includes 
measuring the mass per unit length at the traveling thread. This applies 
both for the measurement of the joint as well as the measurement of the 
thread. Conventionally, the mass per unit length is measured indirectly, 
for example, so that the thread runs through an electric plate condenser, 
and the mean capacitance during the measuring period is a measure for the 
mean mass of the thread section which has run through during the measuring 
period. 
Alternatively, an opto-electrical thread measurement is employed in 
specific cases. 
In accordance with another aspect of the invention, there is provided, in 
accordance with the invention, a joining device capable of traveling and 
forming a joint in an open-end spinning machine having a sliver drawing-in 
device for drawing in a sliver and feeding it to a fiber loosening device 
from which it is guided by a fiber guiding device to a fiber accumulator 
at which the fibers are accumulated, disentangled, imparted with a rotary 
motion, and thereafter engaged with an open end of a thread, and a take-up 
device for drawing the thread out of the fiber accumulator, a thread end 
being feedable, for the purpose of forming a joint, back into the fiber 
accumulator into contact with a quantity of fibers to be joined which had 
been previously fed into the fiber accumulator, the thread being 
continuously withdrawable from he fiber accumulator and fibers being 
continuously feedable into the fiber accumulator, the joining device 
comprising an automatic joint quality measuring device connected to a 
joint quality monitor, and a metering device for quantities of fibers to 
be joined which is controllable in accordance with a means quality of the 
joints, the metering device being operatively connected to the quality 
monitor. 
Because the joining device is movable relative to the open-ended spinning 
machine, in accordance with another feature of the invention, the metering 
device for the quantities of fibers has a detachable operative connection 
with the sliver drawing-in device of the open-end spinning machine. Such a 
detachable operative connection is formed, for example, of a forwardly 
thrustable and withdrawable plunger which acts upon a switch which 
switches the sliver drawing-in device on and off. 
In accordance with a further feature of the invention the automatic joint 
quality measuring device has a thread signal receiver with an output 
connected to a comparator responsive to at least one thread signal 
deviating from those for normal thread values, the comparator has an 
output to which a mean value former of the quality monitor is post 
connected. The thread signal receiver is provided primarily for receiving 
those thread signals which issue from a joint. 
In accordance with an added feature of the invention the joint quality 
monitor has an up/down counter with an up-input connected to an output of 
a comparator responsive to relatively thick locations of the thread, a 
down-input connected to an output of a comparator responsive to relatively 
thin locations of the thread and forming part of the automatic joint 
quality measuring device, and an output connected to the metering device 
for quantities of fibers to be joined. The up/down counter responds only 
to those signals which the comparators let through. In this regard, each 
of the signals let through by the respective comparators, simultaneously 
activate a cleaner section and the formation of a new joint, respectively. 
In accordance with an added feature of the invention, the up/down counter 
is capable of emitting a fiber-quantity increasing signal when a zero 
value is reached and jumping to a prescribed output counter value located 
between zero value and a selective over-run value, and the up/down counter 
being capable of emitting a fiber-quantity reducing signal when the 
over-run value is reached and likewise jumping to the output counter 
value. If the over-run value 8, 9 or 10 is selected, for example, then 
desired output counter values are at 4 or 5. 
In accordance with an additional feature of the invention there is provided 
a corrected quantity adjuster connected to the metering device for 
quantities of fibers to be joined. 
The corrected quantity adjuster can be controllable automatically and, to 
this end, in accordance with an additional feature of the invention, the 
corrected quantity adjuster is connected to the output of the thread 
signal receiver and to the output of the joint quality monitor and is 
capable of emitting a correction signal inversely proportional to the 
number of the joints measured during a just-ended counting process of the 
up/down counter. 
The size of the correction signal is thereby directed thus towards the 
entire number of the joints occurring during the counting process, whether 
they are then counted with or not. 
In accordance with yet another feature of the invention, a corrected 
quantity adjuster is connected to the metering device for quantities of 
fibers to be joined, and wherein the corrected quantity adjuster is 
connected to the outputs of the comparators and to the output of the joint 
quality monitor, and is capable of emitting a correction signal inversely 
proportional to the number of joints which are beyond the quality 
tolerance and which are measured during a just-ended counting process of 
the up/down counter. In this case, with the measurement, the correction, 
thus the "good" joints located within the quality limits, remain 
unconsidered. 
In accordance with yet a further feature of the invention the joint quality 
monitor has at least one device for integrating the joint signals, one 
device for prescribing, similating or integrating the thread signals and a 
comparator device post connected to both of the last-mentioned one 
devices. That which matters is that the integrated joint signals are to be 
compared with the integrated thread signals. These integrated can also be 
prescribed or simulated. Whichever is better in the individual case 
depends upon the spinning conditions as a whole. 
In accordance with yet an additional feature of the invention, the joint 
quality monitor has a first integrator connected in a series-parallel 
circuit with a first comparator and a second comparator, as well as a 
second integrator in a series-parallel circuit with the first and the 
second comparators, the integrators having inputs connected to the joint 
quality measuring device, and the outputs of the comparators being 
connected to the metering device for quantities of fibers to be joined. 
In accordance with a concomitant feature of the invention, the input of the 
first integrator is connected to a first thread signal receiver, and the 
input of the second integrator to a second thread signal receiver. 
Other features which are considered as characteristic for the invention are 
set forth in the appended claims. 
Although the invention is illustrated and described herein as embodied in a 
method and a device for forming a thread joint, it is nevertheless not 
intended to be limited to the details shown, since various modifications 
and structural changes may be made therein without departing from the 
spirit of the invention and within the scope and range of equivalents of 
the claims.

Referring now to the drawing and, first, particularly to FIG. 1 thereof, 
there is shown an open-end spinning machine having a multiplicity of 
open-end spinning units 1 respectively including a sliver drawing-in 
device 2, a fiber loosening device 3, a fiber guiding device 4, a fiber 
accumulator 5 and a draw-off device 6. The sliver drawing-in device 2 is 
formed of a drawing-in roller driven by an electric motor. A switch 7 is 
preconnected to the electric motor. The sliver 8 travels over a feed table 
9 and under the drawing-in roller to the loosening device 3 which is in 
the shape of a rotating, toothed or serrated roller. The fiber guiding 
device 4 is formed as a fiber channel which extends from a housing 10 of 
the loosening device 3 to the fiber accumulator 5. The fiber accumulator 5 
is formed as a rotor which is seated on a shaft 11. Threads 12 which are 
isolated or individually separated by the loosening device 3 initially 
reach a slide surface 13 having a conically shaped casing and extend from 
there into fiber collector grooves 14 formed in the rotating fiber 
accumulator 5. 
The fiber accumulator 5 sets the fibers disposed in the fiber collector 
grooves 14 into rotary motion. They rotate about a common rotary axis of 
the shaft 11 and the fiber accumulator 5 so that the fibers dispose 
themselves lengthwise in the fiber collector grooves 14. 
In the fiber collector grooves 14, the fibers located therein are pieced or 
joined to a thread end 16. A thread 17 to which the end 16 belongs is 
continuously drawn off by means of the draw-off device 6 through a thread 
take-off tube 18 in direction of the arrow 19. The draw-off device 6 is 
formed of a roller pair. 
During a normal spinning operation, the thread 17 follows the broken line 
17'. It is continuously wound on an otherwise nonillustrated cheese or 
crosswound coil. The draw-off device 6 can be changed from forward motion 
to backward or reverse motion for the purpose of effecting the piecing or 
joining and the return of the thread into the fiber accumulator 5. 
A traveling thread piecing or joining device 20 is operatively associated 
with the open-end spinning machine. The thread joining device 20 travels 
from spinning unit to spinning unit and is able automatically to perform a 
piecing or joining operation after a thread break has occurred or a 
first-time piecing or joining operation. For this purpose, the joining 
device 20 remains standing in front of the respective spinning unit and 
performs the individual activities required for piecing or joining, in 
accordance with a given program, for example, controlled by a system of 
cams. 
FIG. 1 shows in a diagrammatic and schematic view only those parts of the 
joining device 20 which are important for an understanding of the 
invention. A thread-joiner quality monitor 22 is connected to an 
automatically operating thread-joiner quality measuring device 21 and has 
an operative connection 23 with a metering device 24 for the quantity of 
joining or piecing fibers which is controllable in accordance with the 
mean quality of the thread joint. A releasable or detachable operating 
connection with the switch 7 of the sliver drawing-in device 2 is formed 
by a line 25 and an electromagnetic drive 26. The connection is formed 
when the electromagnetic drive 26 drives a plunger 27 out which acts 
mechanically upon another plunger 28 of the switch 7 with the objective of 
turning the switch 7 on or, after drawing the plunger 27 back, with the 
objective of turning the switch 27 off again. 
The automatic thread-joining quality measuring device 21 is provided with a 
thread signal pickup or receiver which is formed of a measuring head 29 
and an amplifier 30. The thread signal receiver 29,30 has as its function 
the receiving or picking up of the thread signals originating from a 
thread joint 31. In order to make the thread joint 31 visible on the 
whole, it is shown exaggeratedly enlarged in FIG. 1. With the aid of a 
pair of thread guides 32 and 33, the thread 17 is diverted out of its 
travel path and guided through the measuring head 29 for the purpose of 
picking up the thread signal. Reference may be had to U.S. Pat. No. 
4,327,546 to Derichs et al dated May 4, 1982 which describes the formation 
of the path of the thread during the joining operation. Two comparators 34 
and 35 are postconnected to the amplifier 30. The comparator 34 is 
responsive to relatively thick locations while the comparator 35 is 
responsive to relatively thin locations. The limiting value of a thick 
location is adjustable to a limiting value transmitter 36 while the 
limiting value of a thin location is adjustable to a limiting value 
transmitter 37. 
The thread-joint quality monitor 22 has an up/down counter 38, the up-input 
39 of which is connected to an output 41 of the comparator 34 which is 
responsive to thick locations. A down-input 40 of the up/down counter 38 
is connected to an output 42 of the comparator 35 which is responsive to 
thin locations. The operative connection 23 is connected to the output of 
the up/down counter 38 and leads to the piecing or joining sliver metering 
device 24. 
The joining or piecing sliver metering device 24 includes a computer 43 
which, starting from a base value of the quantity of fibers in the joining 
sliver, converts the correction signals introduced via the operative 
connection 23 into control signals for the electromagnetic drive 26. The 
base value of the amount of joining-sliver fibers can be adjusted to a 
nominal-value transmitter 44. The nominal value transmitter 44 is 
connected to the computer 43 via an analog/digital converter 45. The 
corrected fiber quantity value in the case of the respective decrease or 
increase in the quantity of fibers in the joining sliver is introduced 
into the computer 43 through a nominal value transmitter 79. From an 
output of the computer 43, a line 25 extends via a signal converter 46 
which selectively emits analog or digital control signals as correction 
signals for the silver drawing-in device 2. The quality of the joint 31 is 
determined, for example, capacitively, as it travels through the measuring 
head 29, the measuring signal is amplified and fed to the two comparators 
34 and 35. If the joint 31 meets the quality requirements or 
representations, no signal is issued by either of the two comparators. No 
change is accordingly made in the joining quantity of fibers, and it 
remains the same as it would be when set to the nominal value transmitter 
44. If the comparator 34 determines, however, that the joint 31 is to be 
considered to be a thick location, it issues a signal via the output 41 
thereof which, via a line 47, triggers or activates a non-illustrated 
cleaner section and causes a repetition of the joining or piecing 
operation. Simultaneously, the signal is transmitted via the up input 39 
to the up/down counter 38 which, for example, may be set at the number 5. 
The counter then jumps to the number 6. As before, no signal is 
transmitted any farther via the operative connection 23. 
If the thread joint is in order, the two thread guides 32 and 33 deliver 
the thread 17 into the normal travel path 17' thereof, and the joining or 
piecing device 20 travels farther upon demand or on a search or hunt of 
its own to a different spinning unit. At the latter non-illustrated 
spinning unit, it repeats the foregoing process after the joining or 
piecing operation and, if the comparator 35 then, for example, determines 
that a thin location is present at the joint 31, a signal is transmitted 
via the output 42 which likewise triggers a cleaner section via a line 48 
and causes a repetition of the piecing or joining operation. The signal 
goes simultaneously via the down-input 40 into the up/down counter 38 
which then, for example, jumps back from the number 6 to the number 5. 
From spinning unit to spinning unit, the forward and backwards or upwards 
and downwards jumping of the counter 38 for one or more values can repeat 
for some time without reaching zero value or the preselected overrun 
value. 
The instant the up/down counter 38 has reached zero value, however, it 
issues a fiber-quantity increase signal via the operative connection 23 
and jumps back by itself to the predetermined output counted value, for 
example, to the value 5. The fiber-quantity increase signal becomes 
triggered in the last-mentioned case because, theretofore, more thin 
locations than thick locations among the thread joints were beyond the 
quality tolerance. The computer 43 then assumes the task of increasing by 
a predetermined amount the quantity of fibers in the pieced or joined 
sliver which is adjusted to the nominal value transmitter. This is 
effected, for example, by increasing the length of the period that the 
electromagnetic drive 26 is switched on. The longer the electromagnetic 
drive 26 remains switched on, the longer it also keeps the switch 7 
switched on and the longer the sliver drawing-in device 2 runs so as to 
feed the sliver 8 to the fiber loosening device 3. The latter, in turn, 
feeds or advances a somewhat greater quantity of fibers into the fiber 
collecting grooves 14, and this increased quantity of fibers finally also 
reinforce or thickens the joint 31 which develops the instant a thread is 
returned into the fiber accumulator 5 by running back through the 
drawing-in device 6, so that the end of the thread engages the fiber ring 
disposed in the fiber collecting groove 14. 
If the thick locations were exceeded, the up/down counter 38 would run 
over, for example, when the counter value reaches 10, and would transmit a 
fiber-quantity reduction signal via the operative connection 23. 
Thereafter, the counter value would also drop down to the starting counter 
value, for example, the value 5. The computer 43 would have evaluated the 
fiber-quantity reduction signal by reducing the switched-on time of the 
electromagnetic drive 26 by a predetermined value, for example, expressed 
in seconds or fractions of seconds. Alternatively, in another example, the 
rotary speed of a motor or the adjustment angle of a stepping motor, which 
frictionally acts upon the sliver drawing-in device, could be varied. 
The corrected switched-on time of the electromagnetic drive 26 remains 
unchanged until the counter 38 again reaches or exceeds zero value. In the 
embodiment of the invention according to FIG. 3, the following differences 
exist with respect to the embodiment of FIG. 1: 
The metering device for the quantity of the fibers being joined, which is 
identified in FIG. 3 by the reference character 24". is connected to a 
corrected quantity adjuster 49 which has as its function to adjust to the 
most desirable corrected quantity from case to case and to present it to 
the computer 43" of the joining fiber-quantity metering device 24". 
The corrected quantity adjuster 49 in FIG. 3 includes a computer 50 with 
three inputs 51, 52 and 53. The input 52 is connected via and 
analog/digital converter 54 and a line 55 to the output of the thread 
signal pick-up or receiver 29, 30. The input 51 is connected to the 
operative connection 23 and therewith to the output of the joint quality 
monitor 22. The input 53 is connected to a nominal value transmitter 56. 
The computer 50 receives a pulse via the input 52 for each measured joint 
31. It counts these pulses received during a counting process of the 
up/down counter 38. The beginning and the end of the counting process are 
introduced into the computer 50 via the input 51. The computer 50 issues a 
correction signal which is inversely proportional to the number of joints 
measured during the counting process, the signal being conducted via an 
operative connection 57 to the input of the computer 43" of the metering 
device 24" for the quantity of fibers being joined. At the nominal value 
transmitter 56, the correction signals can be varied percentagewise with 
respect to the amplitude thereof, for example. The computer 43" then 
measures the change in the quantity of fibers being joined, after 
correction jumps which the computer 50, respectively, provides. Otherwise, 
the embodiment of FIG. 3 is constructed like the embodiment of FIG. 1. 
The embodiment of FIG. 4 is provided with a corrected quantity adjuster 49" 
similar to the embodiment of FIG. 3. The corrected quantity adjuster 49" 
has a computer 50" with four inputs 58 to 61. The input 59 is connected to 
the output 42 of the comparator 35, and the input 60 to the output 41 of 
the comparator 34. The input 58 is connected to the operative connection 
23 and therewith to the output of the joint quality monitor 22. The input 
61 is connected to a nominal value transmitter 62. The computer 50" counts 
the number of joints lying beyond the quality tolerance and measured 
during the counting process, and emits a correction signal inversely 
proportional to the number of these joints, the magnitude of the signal 
being determined percentagewise via the nominal value transmitter 62. The 
end of a counting process and the beginning of a new counting process is 
fed to the computer 50" via the input 58. An operative connection 63 
exists between the output of the computer 50" and the computer identified 
in FIG. 4 by the reference character 43" of the metering device for the 
quantity of fibers to be joined which is identified in FIG. 4 by reference 
character 24". 
Otherwise, the embodiment according to FIG. 4 is constructed like that of 
FIG. 1. 
In the construction of the embodiment of FIG. 5, the following differences 
with respect to the embodiment of FIG. 3 exist: 
The metering device for the quantity of fibers being joined, which is 
identified in FIG. 5 by the reference character 24" is connected to a 
corrected quantity adjuster 49'. The corrected quantity adjuster 49' has 
the function of adjusting to the most desirable corrected quantity from 
case to case and to feed it to the computer 43" of the metering device 
24". 
The corrected quantity adjuster 49' includes a computer 50' with three 
inputs 51', 52' and 53'. The input 52' is connected via an analog/digital 
converter 54', an integrator 78 and a line 55 to the output of the signal 
pick-up or receiver 29, 30. The input 51' is connected to the operative 
connection 23 and therewith to the output of the joint quality monitor 22. 
The input 53' is connected to a nominal value transmitter 56'. The 
integrator 78 receives the thread signals of the joints via the line 55. 
The computer 50' receives a pulse for each measured joint 31. The computer 
50' divides the result of the integration through the number of pulses 
received during a counting process of the up/down counter 38. The 
beginning and ending of the counting process is introduced into the 
computer 50' via the input 51'. The computer 50' emits a correction signal 
proportional to the mean thread signal of the joint measured during the 
counting process, the correction signal being conducted via an operative 
connection 57' to the input of the computer 43" of the metering device 24" 
for the quantity opf fibers being joined. At the nominal value transmitter 
56', the correction signals can be varied percentagewise, for example, 
with respect to the magnitude thereof. The computer 43" then measures the 
change in the quantities of fibers to be joined after correction jumps 
which are provided thereto, respectively, by the computer 50'. 
In the embodiment of the invention according to FIG. 2, all of the parts of 
the open-end spinning unit 1 shown in FIG. 1 are also provided. A joint 
quality monitor 22', followed by a metering device 24' for quantities of 
fibers being joined, is connected to the joint quality measuring device 
identified in FIG. 2 by the reference character 21'. 
The joint quality measuring device 21' includes the thread guides 32 and 33 
as known from FIG. 1, as well as the thread signal pick-up or receiver 
likewise known from FIG. 1 and formed of the measuring head 29 and the 
amplifier 30. In addition, a second thread signal receiver is provided 
which is formed of the measuring head 29' and the amplifier 30'. The first 
thread signal receiver 29, 30 picks up the signal of the joint 31, and the 
second thread signal receiver 29, 30' the signal of the thread 17. The 
output 64 of the amplifier 30 is connected to a comparator 66 and to a 
first integrator 69. The output 65 of the second amplifier 30' is 
connected to the same comparator 66 and to an integrator 70. The output 71 
of the integrator 69 is connected to inputs of two comparators 67 and 68. 
The output 72 of the second integrator 70 is connected to inputs of the 
same comparators 67 and 68. An operative connection 73 extends from the 
comparator 67 and a further operative connection 74 from the comparator 68 
to the computer 43' of the metering device 24' for the quantities of 
fibers being joined. 
The comparator 66 is so adjusted that whenever the signal of the joint 31 
deviates from the signal of the thread by a prescribed tolesrance, a 
thread-cleaner signal is emitted via a line 75 with the result that the 
thread is severed and a new joining process is initiated. Deviations below 
the tolerance are disregarded. 
The integrator 69 is provided with an adder 76. The integrator 69 is 
thereby able to issue an aggregate signal via the output 71. The 
integrator 70 is also provided with an adder 77 and is therefore able also 
to issue an aggregate signal via its output 72. The comparator 67 is 
responsive if the aggregate signal coming from the adder 76 and above a 
prescribed tolerance is greater than the aggregate signal coming from the 
adder 77. Deviations below the tolerance are disregarded. Because this 
means that the joint is thicker than is desired, a signal to reduce the 
quantity of fibers being joined is transmitted via the operative 
connection 73 to the computer 43'. The comparator 68 is responsive if the 
signal coming from the adder 76 and greater than a prescribed tolerance is 
smaller than the signal coming from the adder 77. Deviations below the 
tolerance are disregarded. Because this means that the joint on average is 
thinner than desired, a signal to increase the quantity of fibers being 
joined is transmitted via the operative connection 74 to the computer 43'. 
In the description of FIG. 2, those parts which are not specifically 
mentioned are the same as those of similar reference numerals shown in 
FIG. 1 and described hereinbefore. 
As mentioned hereinbefore, the invention is not limited to the embodiments 
represented and described herein. 
In the embodiments of the invention, the computers receive analog signals 
via analog/digital converters. Alternatively, digital signals can however 
be fed thereto as well to provide nominal values or measurement signals. 
Analog/digital converters would be superfluous in such cases. 
In the embodiments according to FIGS. 1 and 2, the nominal value entry of 
the corrected fiber quantities which are applicable or important to the 
respective metering devices 24 and 24' for the quantities of fibers being 
joined, occurs digitally by hand through nominal value transmitters 79. In 
lieu thereof, the possibility exists of deriving from spinning conditions, 
such as, for example, draft, turning or twist and takeup speed, applicable 
quantities of fibers being joined which must be taken into consideration 
with a change in the quantity of fibers being joined, and to introduce 
them as variable nominal values digitally or analogically via 
analog/digital converters into the respective computers 43 and 43'. 
In the embodiments described hereinbefore, the limiting values are 
introduced into the comparators of the joint quality measuring devices by 
means of manually adjustable limiting value transmitters. In lieu thereof, 
the possibility is also afforded of deriving these limiting values from 
thread signals which are picked up by a measuring head connected at least 
temporarily to the limiting value transmitter. In this regard, for 
example, the same measuring head 29 which receives the thread signals of 
the joint is suitable. A time sequence can be maintained so that the 
measuring head, for example, measures the thread first and the limiting 
value transmitter is adjusted in accordance with the thread signal. 
Thereafter, the same measuring head measures the thread signal of the 
joint. The time sequence can be derived, for example, from the measured 
rotary angle of a take-up roller of the take-up device, quite like the 
beginning and the ending of a respective measuring process. In this 
regard, when the thread signal is measured, the joint cannot be missed.