EP1360352A1 - Method and device for identifying and removing foreign matter in fiber material, especially in raw cotton - Google Patents

Abstract

The invention relates to a method and to a device for identifying and removing foreign matter in fiber material in several stages, which is characterized in that the sensor systems react to foreign matter of the same type. When distributed across a conveyor path (2), various sensor systems (4, 4', 4') and the pertaining removal devices (5, 5', 5') are thus capable of removing foreign matter (7, 7', 7') that may optionally have different sizes. The individual removal stages are advantageously positioned along the conveyor path in such a manner that the increasing dissolution degree of the fiber material and the concurrent diminution of the fiber substances are taken into consideration in an optimum manner.

Description

Method and device for recognizing and eliminating foreign substances in fiber material, in particular in raw cotton

The invention relates to a method and a device for recognizing and eliminating foreign substances in fiber material, in particular in raw cotton, according to the preamble of claims 1 and 11 or 2 and 12. In particular in the textile industry it is essential before the fibers are spun into yarn, that foreign substances are removed in order to avoid disrupting the processing process. The term “foreign substances” is understood to mean, in particular, fabrics, cords, foils and fibers which do not belong to the fiber material specified in the yarn (for example polypropylene fibers in the material for the production of cotton fibers). Furthermore, however, those substances are also to be understood as being those which are related with plant fibers they belong to the plant, but they are undesirable in the subsequent processing of the fibers, for example trash parts, nits, seeds etc. The term “fiber material” is understood to mean fibrous structures of limited length, in particular textile fibers. This can be natural, chemical or industrial fibers.

Numerous comparable methods and devices for the treatment of cotton fibers in spinning mills have become known, where the excretion of the foreign substances has to be integrated into a continuous work process between the opening of the cotton bale and the stretching of the card sliver. Depending on the foreign substances to be separated out, the sensor arrangements are metal detectors, line scan cameras, infrared sensors, etc. The separation can take place either by deflecting the contaminated partial quantity by means of a deflection flap or by means of a pressure surge. According to WO 96/35831, it is proposed in a device of comparable generic type to use a plurality of sensor arrangements in succession which react to different parameters, for example, in addition to the line scan camera, at least one sensor which operates in the near infrared range. This is intended to ensure that substances can also be excreted on the downstream separating device which, because of their nature or because of their position in the fiber stream, only trigger a detection signal on one of the two detection parameters.

DE-A 195 16 569 has also disclosed a device of the same type, in which not only two sensor arrangements responding to different detection parameters are provided, but also two different separating devices. An optical sensor system for detecting foreign fibers, plastic parts, etc. follows a detector plate for recognizing metal parts. While the detector plate activates a deflection flap arranged downstream, foreign substances which are recognized by the optical sensor system are blown out of the transport channel by a pressure pulse.

A method for the rapid detection and removal of differently colored foreign substances in fibers has become known from US Pat. No. 5,626,273. In this case, a pneumatically introduced flock stream is first freed of the conveying air at a condenser and then compressed with a conveyor belt to form a compact fleece, which is passed along a transparent shaft wall equipped with sensors. Several sensors are lined up in columns on the shaft wall in order to achieve better efficiency in the detection or to achieve higher transport speeds. to enable. However, a sensor column controls only a single separation device at the end of the shaft.

Finally, US Pat. No. 4,657,144 has disclosed a method and a device for the detection and removal of foreign material in a particle stream which is of a non-generic type. It is primarily tobacco in different forms. However, the material flow is not transported in a closed conveyor system, but falls at the end of an open conveyor belt in free fall as a cascade onto a second conveyor belt below. Two detectors can be arranged one after the other on the vertical drop path, one on each side of the material flow, in order to achieve better penetration. When a foreign substance is detected, the material flow is temporarily diverted with the help of a pressure pulse in order to separate out the contaminated part. Such a method is completely unsuitable for the treatment of fiber material, in particular raw cotton in the spinning mill.

The known methods and devices have the disadvantage that they are not yet optimally coordinated with the entire processing process and that the various processing stages, for example in the blow room of a spinning mill, are only insufficiently taken into account. On the one hand, it is desirable to remove foreign material as completely as possible at the earliest possible point in time immediately after opening the bale. On the other hand, due to the low degree of resolution, the material at this point in the treatment line cannot yet be presented to a sensor arrangement in such a way that even fine foreign substances can be eliminated in a targeted manner. However, if the elimination process takes place too late, it will initially become compact Foreign matter is increasingly dissolved or frayed, which makes subsequent detection and elimination more difficult.

It is therefore an object of the invention to provide a method of the type mentioned at the outset which enables an optimization of the foreign substance excretion taking into account the absolutely necessary treatment stages for the fiber material. The method is also intended in particular to reduce the amount of machine work involved. In terms of the method, this object is achieved with a method with the features in claims 1 or 2 and in terms of the device with a device with the features in claims 11 or 12.

It has surprisingly been found that a multi-stage approach to excretion, i.e. Multiple detection of foreign substances of the same type and subsequent subsequent elimination bring about considerable improvements in efficiency. In particular, the ever-increasing degree of dissolution of the fiber material can be optimally exploited in that the probability increases significantly with increasing degree of dissolution that a foreign material is recognized and eliminated at at least one detection level. Since at least one treatment of the fiber material is carried out on a treatment agent, in particular on a treatment machine, between at least a first excretion and at least a second excretion, the entire process is optimized. Treatment agents can e.g. also only around a certain machine element such as act as a dissolving or rectifying body.

The method according to the invention and the associated device are particularly suitable for the treatment of raw cotton in a spinning mill, in particular in the blow room and Card room. The relevant work processes and work machines are described, for example, in W. Klein, "Die Kurzstapelspinnerei" Volume 2, publisher: The Textile Institute. Of course, use in connection with the processing of other vegetable, synthetic or animal fibers is also conceivable.

To take advantage of the different degree of opening in the detection of foreign matter, it is particularly expedient if the degree of opening of the fiber material between the at least two sensor fields is increased by at least one opening element for the fiber material. The successive sensor arrangements can react, for example, to foreign substances of different sizes, shapes or consistencies. With an even smaller degree of opening, only very large foreign substances are excreted, for example, which occur less frequently. As the degree of opening increases, finer foreign matter is then excreted, the improved presentation on the sensor field also allowing more targeted excretion and thus a reduction in the fibers ejected together with the foreign material.

The successive sensor arrangements can easily react to different detection parameters for the same type of foreign matter. For example, it would be conceivable to detect plastic material with different optical sensors in different wavelength ranges.

The detection and elimination before or after at least one treatment machine for the fiber material is particularly optimal. This can be, for example, a coarse cleaner, a fine cleaner or a fiber mixer. The treatment machine is itself with one or more Opening organs provide or act as an opening organ itself. However, it is also conceivable to carry out at least a first excretion and at least a second excretion directly on the same treatment machine for the fiber material. This provides a multifunctional and compact treatment machine, with which the overall machine effort can be reduced.

If the conveying of the fiber material with pneumatic conveying means takes place in a fiber transport line, it can also have an advantageous effect if at least one first excretion and at least one second excretion takes place directly on the fiber transport line. In this way, it is not necessary to separate the fiber material from the conveying air in order to carry out the two detection or separation processes. Due to the different presentation behavior in the sensor field, it can also be very advantageous if the conveying of the fiber material is carried out alternately with pneumatic conveying means in a fiber transport line and without pressure with mechanical conveying means and / or under the influence of gravity, and if at least a first excretion is carried out directly on the fiber transport line and at least a second excretion takes place on the unpressurized section or vice versa. For example, it could be useful to remove relatively large foreign matter directly on a fiber transport line, while, for example, smaller contaminants on a non-pressurized non-woven fabric can be better recognized and more specifically eliminated.

Elimination at the at least two different separation devices can take place by means of a pressure pulse or by suction. A deflection by deflection flaps or a combination of different separating means is also conceivable. It has proven to be particularly advantageous if the fiber material is guided along a helical conveyor path and if the foreign material is repeatedly recognized and excreted at different points on the peripheral region of the helix. In this area, the fiber material travels a relatively long distance on the smallest volume and, due to the forced screw line, is intensely swirled. This also increases the likelihood that a foreign substance will reach a peripheral area of the material flow and can be recognized by one of the sensor arrangements.

In a coarse cleaner or mono-roller cleaner known per se, a helical fiber throughput is already achieved around a cleaning roller, with foreign matter such as sand, shell parts and the like being mechanically and sensorlessly excreted on a separating grate. Such a treatment machine can therefore be particularly optimized if foreign material is detected on preferably more than two sensor fields at different points on the helical line and subsequently excreted on several separating devices.

A particularly advantageous use of the multi-stage detection is also possible if the treatment machine is a fine cleaner with at least one cleaning roller and if a first separating device is arranged in front of the cleaning roller and a second separating device is arranged after the cleaning roller.

Finally, it is also conceivable that a sensor arrangement and a separating device each form a separating module and that in a fiber treatment line at least two separating modules are arranged at different process stages. Of course, several such modules could also be coupled together to form a compact detection and separation battery.

Embodiments of the invention are described in more detail below and are shown in the drawings. Show it:

FIG. 1 shows the schematic representation of a cleaning line with a carding machine,

FIG. 2 shows a diagram with the dissolution behavior of the fiber material on the line according to FIG. 1,

FIG. 3 shows a schematic illustration of the multi-stage separation principle with three units,

FIG. 4 shows a schematic illustration of a fine cleaner with two separation stages,

FIG. 5 shows a schematic side view of a mono-roller cleaner or coarse cleaner,

Figure 6 is a perspective view of the cleaner according to Figure 5, and

Figure 7 shows an alternative embodiment, each with a separate and an integrated separation module.

Figure 1 shows a treatment line 8 in a blow room / carding machine. In this case, 10 cotton fibers are removed from a bale feed 9 with pressed cotton bales by means of a bale removal machine and into a pneumatic fiber transport line 28 fed. On a metal separator 11, metal parts are first recognized and removed before the fiber material is fed to a coarse cleaner 12. This can be a mono-roller cleaner, for example, as will be described in more detail below with reference to FIGS. 5 and 6. After the rough cleaning, the line is divided into two or more parallel lines, each with the same type of treatment machine. In the present case, the fiber material first passes a first spark separator 13a, which detects and eliminates embers caused by sparking. The fiber material is then fed to a mixer 14, in which fiber material from different batches can be mixed in a manner known per se. In a further treatment zone, the fine cleaning takes place on a fine cleaner 15 before the material passes a second spark separator 13b. Only now does the fiber material get into the cards 16, with a detection of foreign material also being conceivable in front of the card, in the card or after the card. The fiber material is practically transported from the bale cutter 10 to the card 16 in a closed conveyor system which is shielded from the outside. This is not only necessary in order to achieve correspondingly high conveying speeds, but also to avoid the development of dust and additional contamination.

The diagram according to FIG. 2 shows the opening of the fiber material according to the various blowroom machine levels up to the card in cubic centimeters per gram. Of course, this is only an example, whereby the course of the curve can vary depending on the application. However, the degree of opening increases relatively strongly at the bale milling machine and at the rough cleaning stage, the curve flattening out towards the card and therefore no significant improvement in the degree of opening can be achieved. FIG. 3 shows schematically how fiber material 1 is transported over a specific conveyor path 2 and how it is carried out on three different stages 6, 6 ', β''by means of a sensor arrangement 4, 4' and 4 '' or by means of a separating device 5, 5 ', 5''foreign material 7, 7', 7 '' is excreted.

The conveyor section 2 can extend practically over the entire blowroom line according to FIG. 1 or even only over a very specific section thereof. Depending on this, the degree of opening in the sense of FIG. 2 will also be very different in the first stage in relation to the last stage. With appropriate programming of the sensor arrangements 4, 4 ', 4' ', foreign substances of different sizes can also be eliminated in a targeted manner. B. the foreign matter 7 at the first stage are significantly larger than the foreign matter 7 '' at the last stage.

The sensors and separation devices of the individual stages are controlled via a central control unit 17 or via a corresponding computer. Various parameters could be programmed on an input console 32 and it would also be conceivable to switch off individual treatment stages. The control unit 17 is connected to the sensor arrangements or to the separation devices via control lines 31. Of course, remote control would also be conceivable, for example via radio remote control.

FIG. 4 shows, for example, the use of a multi-stage separation using the example of a fine cleaner 15. The fiber material first arrives via the fiber transport line 28 to a dissolving unit 18, possibly with a buffer shaft connected upstream. The opening unit can have a pair of pin rollers. sen, which is integrated in the transport line 28. In certain cases, the pin rollers could also be replaced by brush rollers. The flexibility of the individual bristles has the advantage over rigid pins that larger impurities are not torn apart. The structure of the bristles could even be matched to the properties of the most common types of contamination to ensure that they stick to the bristles. Special cleaning zones on the brush rollers, on which the bristles are cleaned of the foreign material carried along, would also be conceivable. The rollers of the roller pairs can rotate in the same direction or in opposite directions, at the same or at different speeds. Dissolving units of the same type could be used in particular in front of the sensors in every blow molding machine or in the feed shaft of the card.

The dissolved fiber flakes are then fed to a feed shaft 20 and presented to the mutually arranged sensor arrangements 4 in a first sensor field 3. Detected foreign matter is blown into the foreign matter container 26 on the first separating device 5 with the aid of a pressure surge.

At the end of the feed shaft 20, the fiber material passes between a screen roller 21 and a blind roller 22, with conveyed air laden with dust being discharged through the exhaust line 19 via the screen roller 21. The fiber material is fed to the cleaning roller 24 via the feed rollers 23 without pressure. This is provided with nose disks or with a saw tooth set and tears the fiber material over a grate 25 arranged on the peripheral area. Here, primarily fine dirt particles such as e.g. B. excreted sand or parts of plants, seeds and the like. A feed line 27 then becomes tangential again Conveyed air is supplied in order to feed the fiber material back into a fiber transport line 28.

Immediately after leaving the cleaning roller 24, the fiber material passes a second sensor field 3 'with the two mutually arranged sensor arrangements 4'. The foreign substances detected on the sensor field 3 'are separated out in the second separating device 5' and again discharged into the foreign matter container 26 'with a pressure surge. Obviously, the degree of dissolution of the fiber material after passing through the cleaning roller 24 is greater than before. The sensor arrangements and the separation devices are in turn controlled by a central control unit 17.

The coarse cleaner or mono-roller cleaner 12 shown in FIGS. 5 and 6 has a cleaning roller 29 provided with pins, which cooperates with an adjustable grate 30 over a certain circumferential area. The fiber material runs through this roller with the aid of an axial conveying air flow on a helical conveyor path, with corresponding guide plates on the housing surrounding the cleaning roller supporting this conveying course.

The fiber material is flung up after the brushing past the grate 30 and swirled strongly in the process. Along the helical conveyor section, a plurality of sensor arrangements 4 to 4n, for example a total of 10 sensor arrangements, are provided, which cooperate with corresponding separation devices 5 to 5n. These separating devices can be arranged tangentially to the cleaning roller, for example shortly before the fiber material is drawn over the grate 30 again. In this way it is also possible to blow out into a foreign substance container 26 by means of a pressure surge. As indicated in FIG. 6, the individual sensors 4 to 4n could also be replaced by a single sensor 4x, for example by a line scan camera, the signals of which, however, can be precisely identified in terms of position so that the corresponding separating device can be controlled.

Of course, a multistage detection and removal of foreign matter could also be carried out on another cleaning machine, for example on a step cleaner or on a roller cleaner, according to the same basic principle.

FIG. 7 shows a further exemplary embodiment with a gradual material separation, a separate sensor module and a sensor and separation module integrated in a treatment machine being used. After a mixer 14, for example of the Rieter "Unimix" type, a separate separating module 33, for example of the Jossi type "The Vision Shield", is arranged. The fiber material then passes into a fine cleaner 15, which can have the same or a similar structure as that in the exemplary embodiment according to FIG. 4. The sensor arrangement 4 'and the separating device 5' are here integrated directly into the cleaner.

The mixer 14 is provided with vertical filling shafts 34 in a manner known per se. A conveyor belt 35 at the bottom of the mixer transports the various batches of fibers from the filling shafts to a needle-punched cloth 36 which continuously strips off fibers and conveys them to the mixing chamber 37. Scraper rollers 38 ensure that only a metered amount of fiber is fed to the cleaning unit 39. This works in a similar way to the fine cleaner 15 already described. Foreign matter detection and excretion already take place, directly integrated into the mixer.

The excretion module 33 could, for example, be programmed such that only relatively large-sized foreign substances are excreted here. The elimination of the finer foreign matter then takes place with a further increased degree of opening of the flakes on the fine cleaner 15.

Instead of the arrangement shown in FIG. 7, the fine cleaner 15 could also be a conventional type without an integrated separating device, e.g. B. a fine cleaner, type Rieter B50. This conventional fine cleaner could in turn be connected to a separate separation module 33 of the same type as the upstream module. Of course, the setting of the downstream module would be adapted to the changed degree of dissolution after the fine cleaner.

Claims

claims

1. A method for recognizing and eliminating foreign substances in fiber material, in particular in raw cotton, in which the fiber material (1) is passed along at least two sensor fields (3, 3) in succession along a conveyor path (2) and thereby at least one each at each sensor field sensor arrangement (4, 4 ^λ ) reacting to foreign substances is monitored, the contaminated part of the fiber material being separated downstream in relation to the conveying direction upon detection of a foreign substance, the separation taking place on at least two different separating devices (5, 5) on the conveyor line and each separating device is controlled by at least one sensor arrangement upstream of it, characterized in that the sensor arrangements (4, 4 ') react to foreign substances of the same type.

2. A method for recognizing and eliminating foreign substances in fiber material, in particular in raw cotton, in which the fiber material (1) is guided past at least two sensor fields (3, 3 ') in succession in a closed, preferably pneumatic conveyor system along a conveyor path (2) and each sensor field is monitored by at least one sensor arrangement (4, 4 ') which responds to foreign substances, the contaminated part of the fiber material being separated downstream in relation to the conveying direction when a foreign substance is detected, the separation on at least two different separating devices (5, 5 ') takes place on the conveyor line and each separating device is controlled by at least one sensor arrangement upstream of it, characterized in that the sensor arrangements (4, 4') Foreign substances of the same type react and that between at least a first excretion and at least a second excretion at least one treatment of the fiber material takes place on a treatment agent, in particular on a treatment machine (12, 15).

3. The method according to claim 1 or 2, characterized in that the degree of opening of the fiber material between the at least two sensor fields (3, 3 ') is increased by at least one opening member for the fiber material.

4. The method according to any one of claims 1 to 3, characterized in that the successive sensor arrangements react to foreign substances of different sizes.

5. The method according to any one of claims 1 to 4, characterized in that the successive sensor arrangements respond to different detection parameters.

6. The method according to any one of claims 1 to 5, characterized in that at least a first excretion and at least a second excretion takes place on the same treatment machine (12, 15) for the fiber material.

7. The method according to any one of claims 1 to 6, characterized in that the conveying of the fiber material with pneumatic conveying means takes place in a fiber transport line and that at least a first excretion and at least a second excretion takes place directly on the fiber transport line.

8. The method according to any one of claims 1 to 7, characterized in that the promotion of the fiber material alternately This is done with pneumatic conveying means in a fiber transport line and without pressure with mechanical conveying means and / or under the influence of gravity and that at least one first separation takes place directly on the fiber transport line and at least one second separation on the unpressurized section or vice versa.

9. The method according to any one of claims 1 to 8, characterized in that at the at least two different separation devices, the separation takes place by means of a pressure pulse or by suction.

10. The method according to any one of claims 1 to 9, characterized in that the fiber material is guided along a helical conveyor path and that the foreign material is repeatedly recognized and excreted at the peripheral region of the helical line.

11.Device for recognizing and eliminating foreign matter in fiber material, in particular in raw cotton, with a means of conveying the fiber material (1) along a conveyor path (2) to at least two sensor fields (3, 3 ^Λ ), on which the fiber material with at least each a sensor arrangement (4, 4 ^λ ) reacting to foreign substances can be acted upon, and with at least two separating devices (5, 5 ') arranged downstream in relation to the conveying direction, each of which can be controlled by at least one sensor arrangement upstream of it, characterized in that that with the at least two sensor arrangements (4, 4 ') foreign substances of the same type can be recognized.

12.Device for recognizing and eliminating foreign substances in fiber material, in particular in raw cotton, with a conveying means for passing the fiber material (1) in a closed, preferably pneumatic conveying system along a conveying path (2) to at least two sensor fields (3, 3 '), on which the fiber material can be acted upon with at least one sensor arrangement (4, 4 ') which reacts to foreign substances, and with at least two separating devices (5, 5') arranged downstream in relation to the conveying direction, each of which is preceded by at least one of them Sensor arrangement is controllable, characterized in that foreign substances of the same type can be detected with the at least two sensor arrangements (4, 4 ') and that at least one treatment agent, in particular a treatment machine for the fiber material, is present between at least a first separating device and at least one second separating device is ordered.

13. The apparatus of claim 11 or 12, characterized in that between the at least two sensor fields (3, 3 ') at least one opening member is arranged, or extends over the two sensor fields, which increases the degree of opening of the fiber material.

14. Device according to one of claims 11 to 13, characterized in that the successive sensor arrangements (4, 4 ') are set to foreign substances of different sizes.

15. Device according to one of claims 11 to 14, characterized in that the successive sensor arrangements are designed for different detection parameters are .

16. Device according to one of claims 11 to 15, characterized in that at least one first separating device and at least one second separating device is arranged on the same treatment machine (12, 15) for the fiber material.

17. Device according to one of claims 11 to 16, characterized in that the conveying means is a pneumatic conveying means with a fiber transport line (28) and that both separating devices are assigned directly to the fiber transport line.

18. Device according to one of claims 11 to 17, characterized in that the conveying means is both a pneumatic conveying means with a fiber transport line and an unpressurized mechanical conveying means and that at least a first separating device directly the fiber transport line and at least a second separating device the unpressurized section or vice versa assigned.

19. Device according to one of claims 11 to 18, characterized in that the at least two different separating devices can be activated with a pressure pulse or by means of negative pressure.

20. Device according to one of claims 11 to 19, characterized in that the conveyor line extends helically and that the sensor arrangements and the separating devices on the peripheral region of the helix are arranged.

21. The apparatus of claim 16 and 20, characterized in that the treatment machine is a coarse cleaner (12), wherein the conveyor line runs around a cleaning roller on which foreign matter of a different type can be mechanically and sensorlessly excreted via a separating grate.

22. The apparatus according to claim 16, characterized in that the treatment machine is a fine cleaner (15) with at least one cleaning roller and that a first separation device is arranged in front of the cleaning roller and a second separation device after the cleaning roller.

23. The device according to claim 11 or 12, characterized in that a sensor arrangement and a separating device each form a separating module and that in a fiber treatment line at least two separating modules are arranged at different process stages.