Apparatus for determining quantities of fiber conveyed through a duct

An apparatus which determines quantities of textile fiber material during conveyance thereof by an air stream through a duct, includes a sensor unit situated at the duct and arranged for monitoring the stream flowing through the duct and composed of a fiber/air mixture. The sensor unit comprises a plurality of side-by-side situated light emitters forming an emitter bank and a plurality of side-by-side arranged light detectors forming a detector bank. The detector bank is situated spaced from and opposite to the emitter bank for providing a passage for the stream therebetween.

CROSS REFERENCE TO RELATED APPLICATION 
This application claims the priority of Federal Republic of Germany 
Application No. P 38 11 332.5 filed Apr. 2nd, 1988, which is incorporated 
herein by reference. 
BACKGROUND OF THE INVENTION 
This invention relates to an apparatus in the field of spinning preparation 
and is more particularly concerned with determining the quantities of 
fiber such as cotton, chemical fibers or the like pneumatically conveyed 
through a duct with flow rate control. The apparatus includes a sensor 
unit which monitors the advancing fiber stream. 
In fiber processing machines which serve for the spinning preparation of 
fiber, the momentary fiber quantity actually being conveyed has to be 
determined particularly in case the rate of fiber feed is to be regulated. 
In order to be able, for example, to adapt the feed of a bale opener to 
the fiber material requirement of the subsequent fiber processing machines 
of a fiber processing line, it has to be determined how much fiber 
material the bale opener produces at any given moment. 
A known apparatus comprises an optical barrier assembly which functions as 
a sensor for setting the fiber removal height of the detaching device of a 
bale opener. The optical barrier assembly is formed of a light emitter and 
a photocell (such as a selenium cell) responding to the incident light. 
The emitter and receiver are connected by means of control conductors with 
a switching device, for example, a switching relay station. The optical 
barrier assembly is mounted on the outlet duct for the fiber detached from 
the fiber bales. It is feasible to provide a plurality of light emitters 
and light detectors, whose switching relays are each set to a 
predetermined density of the fiber stream. In such an arrangement where a 
predetermined switching relay is set to respond to a predetermined 
quantity throughput, there is effected, by means of the relay, an upward 
or downward motion of the fiber detaching device (for example, one or more 
sawtooth rollers), together with the housing in which the detaching device 
is accommodated. In this manner there is ensured a constant fiber flow 
rate during the fiber bale opening process. If an optical barrier device 
is used which has a single light emitter and a single detector, all that 
can be determined is whether or not fiber material passes between the 
emitter and the receiver. The actual quantity of the fiber material 
throughput thus cannot be ascertained. In case a plurality of emitters and 
receivers is used with the associated separate switching relays, a 
determination of the actual throughput quantity is also not possible, 
because at each time only stepwise one or the other emitter/receiver pair 
is connected to the associated relay. Since a constant fiber stream is 
being produced, a regulation as a function of a variable fiber stream, 
particularly as a function of the quantity requirements by the 
after-connected fiber processing machines is not possible with prior art 
arrangements discussed above. 
SUMMARY OF THE INVENTION 
It is an object of the invention to provide an improved apparatus of the 
above-outlined type, from which the discussed disadvantages are eliminated 
and which, in particular, makes possible in a simple manner an exact 
determination (measurement) of the conveyed fiber quantities. 
This object and others to become apparent as the specification progresses, 
are accomplished by the invention, according to which, briefly stated, the 
sensor unit of the quantity determining apparatus comprises a light 
emitter bank formed of a plurality of serially arranged light senders and 
a receiver bank formed of a plurality of light detectors. The emitter bank 
and the receiver bank are located opposite one another to allow the fiber 
material to pass therebetween. 
The light emitters send light rays to the light receivers. By virtue of the 
plurality of light emitters and light receivers (light emitter bank and 
light receiver bank) there is obtained a shadow effect which reproduces 
the conveyed fiber tufts on the light receiver bank. The number of light 
receivers on which no light impinges at any given time is a measure of the 
fiber quantity of the fiber quantity momentarily present between the 
emitter bank and the receiver bank. This arrangement permits an exact 
measurement of the fiber material stream, that is, the arrangement makes 
possible to determine the dimension of the fiber tufts or the coherent 
fiber clusters. 
Advantageously, the sensor unit is arranged in a conveyor duct of 
rectangular or square cross section. For this purpose, for example, a duct 
portion of rectangular cross section may be inserted in the fiber 
conveying conduit which has an otherwise circular cross section. 
Advantageously, the light emitter bank and the light receiver bank each 
are flush with the inner wall of the conveyor duct and thus form a 
contiguous part thereof, to ensure that flow-dynamically the fiber 
material remains undisturbed and thus may slide without impediment along 
the inner wall of the duct. In a preferred alternative, the light emitter 
bank and the light receiver bank are situated on the inner wall of the 
conveyor duct and the banks are provided, at least at their upstream 
portions (as viewed in the direction of fiber advance) with fiber tuft 
guide elements. Such an arrangement is particularly adapted for 
retrofitting a conveyor duct and ensuring, nevertheless an undisturbed 
fiber flow. 
The apparatus according to the invention is expediently combined with a 
fiber bale opener which has a fiber detaching device, such as rotary 
toothed rollers which travel over the serially arranged fiber bales and 
whose height is adjusted for each pass. The fiber tufts torn from the 
upper face of the fiber bales by the detaching device are removed from the 
zone of the detachers by an air stream and introduced into a pneumatic 
conveyor duct. The fiber material quantities to be removed from the bales 
by the detacher are controlled by the sensor unit constructed according to 
the invention. The detacher is held in a housing cantilevered to a 
travelling turret propelled back and forth along the fiber bales. 
Advantageously, the sensor unit according to the invention is arranged in 
the stationary suction channel which extends horizontally underneath the 
bale opener turret along its path of travel. The cross-sectional area of 
the stationary channel is relatively large and rectangular, both 
characteristics favoring the installation of the sensor unit therein. It 
is of further advantage that the stationary suction channel is situated in 
a close vicinity to the bale opener permitting short electric connections, 
for example, to the driving arrangements. 
In the alternative, the sensor unit according to the invention may be 
situated in the vertical suction duct situated inside the turret and is 
thus located between the detacher and the stationary suction channel. Or, 
the sensor unit may be situated in a duct portion which adjoins the 
stationary channel downstream thereof as viewed in the direction of fiber 
material advance. According to another alternative, the sensor unit is 
situated at the upstream end of the vertical duct portion, in the vicinity 
of the fiber detaching device. 
According to a further feature of the invention, there are provided two 
light emitter banks and two light detector banks which are arranged 
pairwise, in a 90.degree. offset relative to one another so that they form 
a rectangular outline in which the light beams of the emitters of one pair 
are perpendicular to the light beams of the emitters of the other pair. By 
detecting light beams simultaneously from two directions, the accuracy of 
the measurement can be further increased. 
According to further features of the invention, a plurality of light sensor 
units according to the invention may be arranged in series parallel to the 
direction of fiber advance. While visible light may be used, it is 
particularly advantageous to use infrared light emitter and receiving 
devices in which detection errors normally caused by external light 
interferences (daylight) are significantly reduced. Preferably, pulsating 
infrared light is utilized. 
According to a further feature of the invention, the light emitters and the 
light receivers are connected to a common electronic evaluating and 
control device. The information derived from the individual receivers of 
the receiver bank supplies a total image of the fiber quantity, since the 
individual receivers work simultaneously, in cooperation with one another. 
The electronic evaluating circuit can count the number of the "dark" light 
receivers, add the count and form a mean value. Such a value may be 
modified by empirical values by providing it with a factor or may be 
calculated, for example, by integration. Influencing magnitude as 
correcting values may be the air speed, the type of material (cotton, 
polyester, cellulose fiber, etc.), air quantity and suction output. 
According to a further advantageous feature of the invention the light 
emitters and receivers are coupled to an emitter and detector control 
device which, in turn, is connected to an electronic microcomputer 
control. The latter is coupled with the regulatable driving device for the 
propelling drive of the bale opener for providing a direct adaptation of 
fiber tuft output by changing the travelling speed of the bale opener. 
According to a further feature of the invention, the microcomputer control 
is connected with the drive for the height adjustment (feed) of the 
detaching device of the bale opener. During each pass, the detaching 
device remains at the same height for each bale group even if the 
apparatus according to the invention determines that the fiber material 
quantities are too large or too small. Only after completion of the pass 
is the vertical feed adjusted at the beginning of the consecutive pass. In 
case the apparatus according to the invention is connected with the bale 
opener which thus receives a signal whether or not a downstream-arranged 
machine processes fiber, information about a batch production and a real 
production may be obtained. 
Particular advantages are achieved by positioning the apparatus at certain 
locations, by utilizing a plurality of light receivers and by utilizing a 
microcomputer for evaluation and control. By virtue of the apparatus 
according to the invention, the fiber material stream is correctly 
"measured" by ascertaining the actual outline (size) of the material. It 
is a further advantage that factors (for example, the air speed with which 
the fiber tufts are being forwarded) which significantly affect the 
material detection, may be taken into account with appropriate corrections 
.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Turning to FIG. 1, there is schematically illustrated therein a bale opener 
1 which may be, for example, a BLEN-DOMAT BDT model manufactured by 
Trutzschler GmbH & Co. KG, Monchengladbach, Federal Republic of Germany. 
The bale opener 1 serves for removing fiber tufts from the top of serially 
arranged, stationary fiber bales 2 supported on the floor. The bale opener 
1 has a turret 3 which is supported for turning motion about a vertical 
axis on a truck 4 that may travel on ground-supported rails by means of 
wheels. The turret 3 has an outrigger housing 5 which accommodates a 
detacher 6. The outrigger housing 5 may, together with the detacher 6, be 
moved vertically relative to the turret 3. The detacher 6 is formed, for 
example, by a pair of sawtooth rollers for tearing (detaching) fiber tufts 
from the top surface of the bales 2 as the turret 3 travels along the 
bales. Underneath the turret 3, in the zone of the truck 4, there is 
supported a stationary, horizontally oriented suction channel 7 through 
which the detached fiber tufts pass. During operation, the truck 4, 
together with the turret 3, travels laterally along the free-standing 
fiber bales 2 back and forth as indicated by the arrows A and B, while the 
housing 5 and the detacher 6 travel above the bales 2. Above the detacher 
6 there is arranged, in the outrigger housing 5, a suction duct 6 which is 
coupled to the stationary channel 7 by means of a duct portion 9a and a 
vertical telescoping duct 9 supported in and travelling with the turret 3. 
A blower (not shown) pneumatically connected to the duct series 9a, 9 and 
7 generates an air stream which carries the fiber tufts through the duct 
series away from the detacher 6. 
According to FIG. 1, a sensor unit 10 according to the invention is mounted 
in the stationary suction channel 7 and is electrically connected with an 
evaluating and control device 18. According to FIG. 2, the sensor unit 10 
is arranged in the telescoping duct 9, whereas according to FIG. 3, the 
sensor unit 10 is situated in the suction duct portion 8, at the upstream 
end of the suction duct portion 9a. 
Turning to FIG. 4, the sensor unit 10 comprises a plurality of side-by-side 
arranged light emitters 11a, 11b . . . 11n forming an emitter bank 11. 
Opposite the light emitters there is arranged a plurality of light 
detectors 12a, 12b . . . 12n which, in turn, form a light detector bank 
12. There may be provided, for example, 30 light emitters and 30 to 100 
light detectors. The light beam extending from the light emitters to the 
light detectors is symbolized by parallel arrows. 
FIG. 5 illustrates a component carrier 13 on which there are arranged two 
rows of light detectors 12a to 12n (receiver diodes) such that the light 
detectors of one row are offset relative to those of the other row. The 
resolution depends upon the number of the rows. 
FIG. 6a depicts a condition wherein between the light emitter bank 11 and 
the light detector bank 12 no fiber material is present so that all the 
light beams impinge on a light detector of the detector bank 12. FIG. 6b 
shows the presence of a small quantity of fiber material 14 (fiber tufts) 
between the emitter bank 11 and the detector bank 12, so that only one 
part of the light beams is prevented from reaching detectors of the 
detector bank 12. According to FIG. 6c, a large quantity (cluster) of 
fiber material 14 is present between the light emitter bank 11 and the 
detector bank 12, so that only a few light beams reach detectors of the 
detector bank 12. Thus, in the operational state depicted in FIGS. 6b and 
6c, on the light detectors of the detector bank 12 a shadow appears whose 
area is an indication of the dimension and thus the quantity of the fiber 
material 14. 
Turning now to FIGS. 7 and 7a, there is illustrated therein a conveying 
duct portion 15 in an axial and a radial sectional view, respectively. The 
wall 15a of the duct 15 may be sheet metal. The light emitter bank 11 and 
the light detector bank 12 are mounted in the duct such that their 
respective outer surface is flush with the inner wall face 15b of the duct 
wall 15a. By virtue of this arrangement, the fiber material, travelling in 
the direction as indicated with the arrow G, will encounter no 
obstruction. 
Turning now to FIGS. 8 and 8a, there is shown therein a conveyor duct 15 on 
the inner walls 15b of which there is mounted the light emitter bank 11 
and, opposite thereto, the light detector bank 12. At their upstream end, 
as viewed in the direction of fiber advance, there are provided oblique or 
rounded fiber tuft guide elements 16a and 16b and at the downstream end of 
the banks 11 and 12 there are arranged similar guide elements 17a and 17b. 
As seen in FIG. 8a, the sensor unit is formed of two emitter banks 11 and 
11' arranged at 90.degree. to one another and two detector banks 12 and 
12', also arranged at 90.degree. to one another, so that the four banks 
fully enclose the cross-sectional area of the flow passage. The guide 
elements 16a, 16, 17a and 17b substantially reduce obstructions to the 
material flow that would be caused by the inwardly protruding banks 11 and 
12. 
Turning now to the block diagram illustrated in FIG. 9, the light emitter 
bank 11 and the light detector bank 12 are electrically connected with the 
emitter and detector control device 18 which, in turn, is connected to an 
electronic control device 19 which may be, for example, a TMS 
microcomputer manufactured by Trutzschler GmbH & Co. KG. To the 
microcomputer 19 there are connected a device 20 for inputting 
correctional values (for example, type of material) and a device 21 for 
inputting information concerning additional influencing magnitudes, such 
as air speed. The control apparatus (microcomputer) 19 is electrically 
connected with a device 22 which, in order to apply control signals, is 
coupled with the drive 22 (electromotor) of the truck 4 and the drive 23 
(electromotor) for the vertical adjustment (feed) of the detacher 6 of the 
bale opener 1. 
It will be understood that the above description of the present invention 
is susceptible to various modifications, changes and adaptations, and the 
same are intended to be comprehended within the meaning and range of 
equivalents of the appended claims.