EP4267787A1

EP4267787A1 - Method for operating a device on or in a textile machine, and textile machine operated therewith

Info

Publication number: EP4267787A1
Application number: EP21839068.0A
Authority: EP
Inventors: Peer Duschneit
Original assignee: Truetzschler Group SE
Current assignee: Truetzschler Group SE
Priority date: 2020-12-22
Filing date: 2021-12-10
Publication date: 2023-11-01
Also published as: CN116438337A; WO2022135977A1; DE102020134592A1

Abstract

The invention relates to a device on or in a textile machine (1), having a plurality of cleaning sections (60), each of which comprises a corresponding opening roller (61). The device is designed such that during a rotation of the corresponding opening roller (61) in a specified direction, fiber material is conveyed in at least one corresponding transport direction along the rotational axis of the corresponding opening roller (61) and foreign materials are separated in the process. A transfer section (8) is provided for each pair of directly adjacent opening rollers (61) of two cleaning sections (60), said transfer section being designed such that the fiber material conveyed from one opening roller (61) is transferred to another opening roller (61), which follows the opening roller in the fiber transport direction running substantially transversely to the rotational axis of the opening roller or the other opening roller (61). A method for operating such a device has an operating phase in which, for each pair, the rotational speed of the opening roller (61) is less than the rotational speed of the other opening roller (61). A textile machine (1) according to the invention has such a device.

Description

Title: Method for operating a device on or in a textile machine and textile machine operated therewith

description

The invention relates to a method for operating a multi-roller device or textile machine for cleaning fiber material and a device or textile machine operated therewith.

Such textile machines are known. They are used to remove foreign material coming from an upstream textile machine, such as a bale opener or heavy-part separator, which is intended to separate foreign material from the fiber material detached by the bale opener, which could cause damage to the downstream textile machine (fiber tufts, possibly with other foreign material) from that foreign material separate and open the fiber tufts and transport them to a downstream textile machine such as a mixer.

EP 2 554 726 B1 discloses an opener with a grate to separate foreign material in the form of shells and dirt from a fibrous material to be opened. It is therefore in the professional understanding of a cleaner. This cleaner includes a feeder. The feeder divides the incoming fiber-air flow so that both partial flows meet the first opening roller at a relatively small distance from the center of a first opening roller. Due to its rotation and the presence of guide elements along the outer circumference of this opening roller, the first opening roller transports the incoming fiber material outwards from these impingement points in mutually opposite directions along its axis of rotation to its two ends. After that, the fiber material transferred to an opposite end of a second opening roller. Due to its rotation and again existing guide elements along the outer circumference of this opening roller, the second opening roller transports the fiber material transferred from the first opening roller from its ends inwards towards its center in two mutually facing directions along its axis of rotation. After that, the fiber material brought together in this way is delivered via an outlet to a downstream textile machine. Furthermore, a grate with a cellular wheel sluice arranged underneath is arranged below each opening roller in order to separate the foreign material that has been separated out in each case.

The object of the invention is to improve the transfer of fiber material to be cleaned between two opening rollers of a multi-roller textile machine.

This object is solved by the subject matter of the independent claims. Advantageous developments are specified in the dependent claims.

In a method for operating a device on or in a textile machine, the device has a plurality of cleaning sections, each with an associated opening roller. The device is designed to convey fiber material in at least one corresponding transport direction along the axis of rotation of the associated opening roller when the associated opening roller rotates in a predetermined direction, thereby separating foreign materials. For each pair of immediately adjacent opening rollers of two cleaning sections, there is an associated transfer section designed so that the fiber material conveyed by an opening roller is conveyed to a substantially transverse to the axis of rotation of one and/or the other opening roller running fiber transport direction subsequent, other opening roller is passed. The method has an operating phase in which, for each pair, the speed of one opening roller is lower than the speed of the other opening roller. Surprisingly, it has been found that an increasing speed of the opening rollers in the processing direction means that the fiber material to be cleaned in particular in the transition between two opening rollers is more or less pulled into the area of the other downstream opening roller that receives the fiber material to be cleaned. i.e. the transfer of the material from one opening roller dispensing this material to the other opening roller proceeds more safely. In addition, the risk of a material jam is reduced, particularly in the area of the other opening roller.

The method preferably includes a starting phase as a transition from a rest phase, in which the opening rollers are stationary, to the operating phase. In the starting phase, both opening rollers of at least one pair are moved at the same time. As a result, the upstream, releasing opening roller would be accelerated less strongly than the immediately downstream, receiving opening roller, at least at the beginning. Alternatively or additionally, the upstream opening roller can be made to rotate later than the downstream opening roller. In all of these cases, the speed difference according to the invention is already achieved when starting up.

Alternatively or additionally, the method can have an acceleration phase within the operating phase, in which at least in one pair the speeds of both opening rollers are increased simultaneously or the speed of one opening roller is increased later and/or more slowly in relation to the other opening roller. Such acceleration phases can occur when the production of the device in question or textile machine is to be increased, the cleaning performance is to be changed and/or the fiber material to be cleaned changes.

Accordingly, there can also be a braking phase within the operating phase, in which at least in one pair the speeds of both opening rollers are reduced simultaneously or the speed of one opening roller is reduced earlier and/or more sharply in relation to the other opening roller.

Each of the aforementioned methods can have a stop phase as a transition from the operating phase to the rest phase, in which at least in one pair both opening rollers are stopped simultaneously or one opening roller is stopped earlier than the other opening roller.

In the aforementioned methods with speed change on the respective pair of opening rollers, the speed change of one opening roller can be different than the speed change of the other opening roller, but always associated with the fact that the speed of the other opening roller is higher than the speed of one opening roller.

In this case, an acceleration value of the one opening roller is preferably smaller, at least in a section of the respective phase, than an acceleration value of the other opening roller in the section of this phase. In the case of increasing the speeds of both opening rollers, it remains clearly evident that the speed of the other opening roller is higher than the speed of one opening roller. If the speeds of both opening rollers are reduced, their acceleration values are negative. This makes it clear that one opening roller is accelerated more negatively, i.e. decelerated, than the other opening roller. A device on or in a textile machine has the device described above. The device also includes a drive section. The drive section is designed to drive the opening rollers in rotation. According to the invention, the drive section is designed to operate the device according to one of the aforementioned methods; no special further precautions are necessary. As a result, existing drive sections could be replaced in part or in full, opening up the possibility of retrofitting. Alternatively or additionally, the device has a controller or is coupled to such a controller that is set up to operate the drive section according to one of the aforementioned methods. In the case of retrofitting, an update of the control software for the drive section can be sufficient to implement one of the aforementioned methods.

The drive section preferably includes a drive member rotationally operatively connected to at least the at least one pair of opening rollers. i.e. a single drive element can be sufficient to implement the method according to the invention.

In this case, the drive section can comprise a gear, via which the drive element is rotationally operatively connected to at least one opening roller of the at least one pair. This allows the speed differences in a simple way.

The transmission preferably comprises a traction drive whose traction rollers, which are driven by the drive element via the traction mechanism, are rotationally operatively connected to a respective opening roller. This is a particularly simple way of producing the speed differences according to the invention. Alternatively or additionally, the device has a mechanism that is set up to make the speeds and/or acceleration values of the opening rollers of the at least one pair different. In the case of a traction drive, the speed differences can be influenced by the diameter of the traction pulleys or their number of teeth (when using a toothed belt or a chain as the traction device) and can also be changed by replacing them. The acceleration values can be changed by means of a continuously variable transmission or a multi-speed transmission with automatic gear changing.

A clutch mechanism can be arranged between the opening rollers of the at least one pair. Alternatively, a separate drive element can be provided for an associated opening roller of the at least one pair, which is mechanically decoupled from the one drive element or is coupled to the one drive element in such a way that the separate drive element is able to rotate the rotation transmitted to the associated opening roller to superimpose the one drive element. All of these variants can be implemented using conventional means.

A textile machine according to the invention has one of the aforementioned devices.

The textile machine can be designed as a cleaner, stage cleaner or feeder. The invention can thus be used universally.

Further features and advantages of the invention result from the following description of a preferred embodiment. Show it:

Figure 1 shows a cleaner according to an embodiment of the invention, FIG. 2 shows a vertical sectional view from the rear side in FIG. 1,

Figure 3 shows the flow of material through the cleaning sections of the cleaner of Figure 1,

Figure 4 shows a vertical section from the front in Figure 1,

FIG. 5 shows a method for operating a textile machine provided with opening rollers, according to a first embodiment of the invention,

FIG. 6 shows a method for operating a textile machine provided with opening rollers, according to a second embodiment of the invention and

FIG. 7 shows the two partial processes of the method according to FIGS. 5 and 6 in greater detail.

FIG. 1 shows a textile machine 1 according to an embodiment of the invention in the form of a cleaner. The cleaner 1 comprises a housing 2 which contains the essential operating elements of the cleaner 1. As is known, the housing 2 comprises covers, flaps and a frame which is not visible here and is not designated.

Here at the front of the housing a display 3 is arranged. The purpose of the display 3 is to make operating states, operating processes or even production values visible to the outside.

Above the housing 2 there is an introduction section 20, which serves to carry cleaning sections 60, which will be described in more detail later To feed fiber material, which is enclosed by the housing 2. A feed section 10 serves to connect the introduction section 20 to a fiber-air feed. In the example shown, the feed section 10 consists essentially of two pipes 12, 12 and a sensor 11 arranged between them. The sensor 11 is used, for example, to determine the speed of the fiber-air flow. The right-hand tube 12 opens into a tube section 22 in the example shown. The pipe section 24 in turn opens into an air separator 26 at its end remote from the pipe section 23.

The air separator 26 serves to remove excess (in the extreme case: the entire) amount of air from the incoming fiber-air flow. The remaining stream of material (fibrous material, if necessary with air) is introduced into a first cleaning section 60 which is enclosed by the housing 2 . A motor 21 can also be seen, which deflects the fiber-air stream arriving from the right-hand tube 12 into the tube section 22 or the tube section 23 via a fan 25, which will be explained in more detail later.

A pipe 28 serves to discharge air separated by the air separator 26 to the outside of the cleaner 1 .

The housing 2 is set up on four adjustable feet 5 here. The adjustable feet 5 are used in a known manner to align the cleaner 1 on the installation surface (floor). The cleaner 1 also includes a discharge section 30 for the cleaned fiber material. The discharge section 30 comprises two pipes 31, 32 between which a sensor 33 is arranged.

A discharge section 40 with a pipe 41 is also shown. The discharge section 40 serves to transport separated material (dirt, shells, etc.) out of the cleaner 1 from the incoming fiber-air stream.

FIG. 2 shows a vertical sectional view of the cleaner 1 from the rear side in FIG. The back of the cleaner 1 is exposed in FIG. In addition, the introduction section 10 is omitted. As a result, the view of the pipe section 22 is free insofar as the fan 25 specified above can be seen.

On the outlet side, the air separator 26 opens into a connection 27 which, on the outlet side, opens via an opening 64 in a wall section 63 of the first cleaning section 60 . The wall section 63, in conjunction with a grate 62 arranged on its underside, defines a chamber 67 in which an opening roller 61 is arranged in a known manner so as to be freely rotatable. The opening roller 61 comprises outwardly protruding, rod-like projections, not designated in any more detail, which are used to entrain the fiber material in the chamber 67 .

Furthermore, the cleaner 1 has a second cleaning section 60 with a rear chamber 67 here, which in turn is surrounded by a wall section 63 and an associated, second grate 62 . On its upper side, the rear chamber 67 has an opening, which cannot be seen here, into which a connection 34 of the discharge section 30 opens on the inlet side. On the outlet side, the connection 34 opens into the pipe 31 indicated above.

The fiber material arriving from the air separator 26 is preferably transported horizontally to the right in FIG. 2 by the front opening roller 61 here. In order to accomplish this, guide elements 65 are arranged in the chamber 67 . These guide the fibrous material horizontally to the right in FIG. Below the grates 62 is the discharge section 40 which comprises wall sections 47 in the upper area facing the grates 62 . The wall sections 47 in connection with a cellular wheel 42 of a cellular wheel sluice and with the grates 62 each enclose a (removal) chamber 48 .

In the example shown, the wall sections 47 are formed in such a way that the chamber 48 formed in each case reduces its cross section in the direction of the star feeder 42 . The outer two wall sections 47 border on a wall section 43 at the bottom. The wall section 43 partially encloses the cellular wheel 42 and forms a discharge pipe 44 below the cellular wheel 42. The discharge pipe 44 is open in the direction of the cellular wheel 42. The discharge pipe 44 is hollow inside, so that a discharge space 45 is formed. During cleaning, foreign materials fall through the grates 62 into the chambers 48 in the direction of the star feeder 42. The rotation of the star feeder 42 causes the thrown-off foreign material into the discharge space 45 is managed.

The cellular wheel 42 is designed in a known manner, and its projections preferably have elastic sealing lips which rest against the wall sections 43, 47 or are at such a small distance that the foreign material is safely transported into the discharge space 45. FIG. 3 shows the material flow 4 through the cleaning sections 60 of the cleaner 1. The fiber material reaches the left-hand chamber 67 via the connection 27, is transported helically in the direction of a transfer section 8 by means of the guide elements 65 (not shown here) and is transported into this transfer section 8 due to the centrifugal force acting on them. The centrifugal force means that the fiber material automatically reaches the area of the right-hand chamber 67 . This is made easier by the fact that the right-hand chamber 67 is a smaller distance from the installation surface of the cleaner 1 than the left-hand chamber 67. This allows gravity to be used and the fiber material reaches the right-hand chamber 67 without any major difficulties The opening roller 61 (not shown) in connection with the guide elements 65 arranged here transports the fiber material in a helical manner in the direction of the connection 34. In both chambers 67 foreign material is separated out via the grates 62 (also not shown). With regard to the grates 62, the bearings 66 of the grate bars can be seen in FIG.

FIG. 4 shows a vertical section of the cleaner 1 from the front side in FIG. Windows 6 are preferably formed in or on the housing 2 in order to avoid accumulations of fibers in the respective adjoining chamber 67 . Furthermore, on this side of the cleaner 1, a drive section 70 is formed. The drive section 70 includes a concealed motor, on the output shaft of which a belt pulley 71 is arranged in a rotationally fixed manner. A drive belt 74 is looped around the pulley 71 and another pulley 72 . The belt pulley 72 is arranged in a rotationally fixed manner with respect to the opening roller 61 located behind it and on the right in FIG. The pulley 72 has two levels. The drive belt 74 is looped around in the first plane. A second drive belt 75 is looped around in a second level behind it, which is also wrapped around a third pulley 73. The belt pulley 73 is arranged so that it cannot rotate relative to the opening roller 61 on the left in FIG. This allows the motor to drive both opening rollers 61,61. The pulley 72 preferably has a smaller outside diameter than the pulley 73. As a result, the speed of the opening roller 61 on the right here is higher than the speed of the opening roller 61 on the left. This has the surprising effect that the transported fiber material is pulled apart a little, especially in the area of the transfer section 8 . This promotes the smooth transport of the fiber material through the invisible transfer section 8 even at high production levels and reduces the risk of fiber material accumulating. Overall, this enables smoother operation. In addition, there is a quasi-stretching of the fiber material passing through and, as a result, a certain orientation.

Furthermore, in the arrangement shown, a preferably adjustable tensioning roller 76 is arranged in the area of the drive belt 75 . Such a tension roller can of course also be provided in the area of the drive belt 74 . Alternatively, there is only one drive belt, in which case a tensioning roller can be provided to deflect one drive belt in such a way that windows 7 remain arranged below the drive belt.

The windows 7 are located in the area of the chambers 48 of the discharge section 40 and have the same effect as the windows 6, only in relation to the chambers 48.

Finally, there is a motor 46 which is arranged in a rotationally fixed manner with respect to the cellular wheel 42 . The motor 46 thus puts the cellular wheel 42 in rotation, so that the excreted material can be transported away from the cleaner 1.

The drive section 70 designed in this way functions as follows:

If the drive motor is started up from the idle state (speed=0), the drive motor accelerates the speed of its output shaft, preferably according to a predetermined behavior.

Both pulleys 72, 73 are rotated practically at the same time. Due to the transmission ratio between the belt pulleys 72, 73, the speed of the opening roller 61, here on the right, which is closest to the drive motor in terms of drive, is higher at each waiting time point than the speed of the other left opening roller 61, which is arranged counter to the fiber transport direction. The consequence of this is that the fiber material transferred from the left to the right opening roller 61 is pulled apart to a certain extent through the transfer section 8 .

The speed ratio of the two opening rollers 61, 61 is maintained even during braking by the drive motor until the drive motor is at a standstill.

FIG. 5 shows a method for operating a textile machine provided with opening rollers, according to a first embodiment of the invention.

After a start in step S1, a subsequent step S2 checks whether the opening rollers, which are two in this example, should be accelerated or not. If this is not the case (no branch after step S2), the process jumps back to step S2. Otherwise (yes branch after step S2), the opening rollers of the textile machine are accelerated in a subsequent step S5 in a first sub-process.

If both opening rollers rotate at their target speeds CÜBI or CÜBS, a subsequent step S6 checks whether the opening rollers 61, 61 should be braked or not. If this is not the case (no branch after step S6), the process jumps back to step S6. Otherwise (yes branch after step S6), the opening rollers of the textile machine are braked in a subsequent step S7 in a second sub-process.

After both opening rollers have been braked, it is checked in a subsequent step S8 whether the operation of the textile machine has ended or not. If this is not the case (no branch after step S8), the process jumps back to step S2. Otherwise (yes branch after step S8), a jump is made to step S9, in which the operation of the textile machine with regard to the opening rollers is or is ended.

FIG. 6 shows a method for operating a textile machine according to a second embodiment of the invention. In contrast to the method shown in FIG. 5, in the no branch after step S6 there is a jump back to step S2. Secondly, in the no branch, after step S2 there is a jump to step S6. This procedure has the advantage that it is alternately checked whether the relevant opening rollers should be accelerated or decelerated. This increases the flexibility of use, since this allows the opening rollers to be accelerated and/or braked in stages. This enables, for example, a test run relatively low final speed. If the test is successful, it is accelerated to a higher production speed.

Figure 7 shows the two sub-processes in the methods shown in Figures 5 and 6 in greater detail. FIG. 7a shows the first sub-process from step S5, and FIG. 7b shows the second sub-process from step S7.

According to FIG. 7a, in a first step S51 of the partial process of accelerating two opening rollers arranged directly one behind the other in the fiber transport direction, the rear opening roller, which is faster in operation, is accelerated with an acceleration OBS to a rotational speed CÜBS. At the same time, it is checked in a step S52 whether or not a predetermined waiting time Δtβi has elapsed. If this is not the case (no branch after step S52), the process jumps back to step S52. Otherwise (yes branch after step S52), in a subsequent step S53, the opening roller which is at the front in the fiber transport direction and is slower in operation is accelerated with an acceleration OBI to a rotational speed CÜBI. The following applies: CÜBI < CÜBS. The following can also apply: OBS > OBI. The waiting time Atßi can be 0, which means that step S52 can also be omitted.

According to FIG. 7b, in a first step S71 of the sub-process of decelerating two opening rollers arranged directly one behind the other in the fiber transport direction, the front opening roller, which is slower in operation, is decelerated to a rotational speed CÜAI with a negative acceleration OAI in terms of value. At the same time, a step S72 checks whether or not a predetermined waiting time ΔtAs has elapsed. If this is not the case (no branch after step S72), the process jumps back to step S72. Otherwise (yes branch after step S72), in a subsequent step S73, the rear opening roller, which is faster in operation, is accelerated to a rotational speed CÜAS with an acceleration ciAs that is also negative braked. Either CÜAI<CÜAS or, if the cleaner is stopped: CÜAI=CÜAS=0. The following can also apply here: |QAI| > |C(AS|. The waiting time AtAs can also be 0, which means that step S72 can also be omitted.

In both partial processes, the speeds of both opening rollers 61, 61 preferably differ from one another in such a way that, apart from a state of rest of both opening rollers 61, 61, the rear opening roller 61, which is faster in operation, at any time (i.e. also during acceleration and deceleration) rotates faster than the front opening roller 61, which is slower in operation.

With regard to the cleaner 1 as a special type of textile machine according to the invention, due to the drive section 70 realized there for the opening rollers 61, 61, the following applies: Atβi=AtAs=0, OBS>OBI and |OAI| > |OAS|.

The invention is not limited to the above embodiments.

In the case of a plurality of opening rollers 61 , the drive section 70 can have a separate drive for some of the opening rollers 61 . Furthermore, a clutch can be provided which causes the opening roller 61, which is slower in operation, to be accelerated later compared to the opening roller 61, which is faster in operation, and in contrast, the faster opening roller 61 is braked later compared to the slower opening roller 61. Both variants would represent an implementation of steps S52 and S72.

If waiting times are provided, the opening roller 61, which is slower in operation, can also (temporarily) accelerate faster or slower be braked than the opening roller 61 of the respective pair, which is faster in operation.

It is essential that the final speeds to be achieved by the opening rollers 61, 61 in the direction of fiber transport become ever greater. It is preferably provided that this is also the case at any point in time during the acceleration and braking phases.

Even if the invention is described in relation to a cleaner 1 or a pair of opening rollers 61 , 61 arranged directly one behind the other in the fiber transport direction, the invention can be scaled to any number of opening rollers 61 , 61 . For example, if three opening rollers are provided, steps S53 and S73 could in turn each be replaced by a step S5 or S7, which is then configured according to FIG. 7a or FIG. 7b. Consequently, a nested or cascade-like sequence structure is created for controlling or operating the respective opening rollers.

Instead of a cleaner, the invention can also be applied to other textile machines 1 with several opening rollers 61, 61, such as step cleaners or feeders.

As a result, the invention provides a simple and cost-effective way of making the fiber transport safer, especially during the transfer between two opening rollers arranged directly one after the other in the fiber transport direction, and reducing or even avoiding the risk of fiber accumulation. Last but not least, the stretching effect on the fiber material in this area improves the fiber processing itself and thus the cleaning or opening effect of the textile machine in question. Reference List

1 textile machine

2 housing

3 display

4 fibrous material flow

5 adjustable foot

6 windows

7 windows

8 transfer section

10 feeding section

11 sensors

12 pipe

20 introductory section

21 engine

22 - 24 pipe section

25 fan

26 air separator

27 connection

28 tube

30 derivation section

31, 32 tube

33 sensors

34 connection

40 discharge section

41 tube 42 cell wheel

43 wall section

44 exhaust pipe

45 drainage room

46 engine

47 wall section

48 chamber

60 cleaning section

61 opening roller

62 rust

63 wall section

64 opening

65 guiding element

66 grate storage

67 chamber

70 drive section

71 - 73 pulley

74, 75 drive belts

76 idler pulley

Si; i e N step

Claims

patent claims

1 . Method for operating a device on or in a textile machine (1), wherein

• the device has

- a plurality of cleaning sections (60)

• each with an associated opening roller (61) and

• designed, upon rotation of the associated opening roller (61) in a predetermined direction fiber material in at least one corresponding transport direction along the axis of rotation of the associated opening roller (61)

° to transport and

° while separating foreign materials, as well as

- for each pair of immediately adjacent opening rollers (61) of two cleaning sections (60) an associated transfer section (8), designed so that the fiber material conveyed by one opening roller (61) to another opening roller (61) in a substantially transverse to axis of rotation of the one and/or the other opening roller (61) is transferred to the fiber transport direction running, and

• the method has an operating phase in which, for each pair, the speed of one opening roller (61) is lower than the speed of the other opening roller (61).

2. The method according to claim 1, comprising a starting phase as a transition from a rest phase in which the opening rollers (61) stand still, in the operating phase, in which at least one pair

• both opening rollers (61) are rotated simultaneously or • the one opening roller (61) is rotated later in relation to the other opening roller (61).

3. The method according to any one of the preceding claims, comprising, within the operating phase, an acceleration phase in which at least one pair

• the speeds of both opening rollers (61) are increased simultaneously or

• the speed of one opening roller (61) is increased later and/or more slowly in relation to the other opening roller (61).

4. The method according to any one of the preceding claims, comprising, within the operating phase, a braking phase in which at least one pair

• the speeds of both opening rollers (61) are reduced simultaneously or

• the speed of one opening roller (61) is reduced earlier and/or more strongly in relation to the other opening roller (61).

5. The method according to any one of the preceding claims, comprising a stop phase as a transition from the operating phase to the rest phase, in which at least one pair

• Both opening rollers (61) are stopped simultaneously or

• the one opening roller (61) is stopped earlier in relation to the other opening roller (61).

6. The method according to any one of claims 2 to 5, wherein in the respective pair, the change in speed of an opening roller (61) runs differently than the change in speed of the other opening roller (61).

7. The method according to claim 6, wherein an acceleration value of the one opening roller (61) is smaller at least in a section of the respective phase than an acceleration value of the other opening roller (61) in the section of this phase.

8. Device on or in a textile machine (1),

• formed according to claim 1,

• comprising a drive section (70) designed to drive the opening rollers (61) in rotation, and

• whereby

- the drive section (70) is designed to operate the device according to a method according to any one of the preceding claims, and/or

- The device has a controller or is coupled to a controller set up to control the drive section (70) to operate the device according to a method according to any one of the preceding claims.

9. Apparatus according to claim 8, wherein the drive portion (70) comprises a drive member rotationally operatively connected to at least one pair.

10. The device according to claim 9, wherein the drive section (70) comprises a gear (71-75) via which the drive element is rotationally operatively connected to at least one opening roller (61) of the one pair.

11. The device according to claim 10, wherein the transmission (71-75) comprises a traction drive (71-75) whose from the drive element a traction device (74, 75) driven traction device rollers (72 - 73) are rotationally operatively connected to a respective opening roller (61). Apparatus according to claim 10 or 11, comprising a mechanism arranged to make the speeds and/or acceleration values of the opening rollers (61) of the at least one pair different. Apparatus according to claim 12, comprising

• a clutch mechanism arranged between the opening rollers (61) of the at least one pair or

• for an associated opening roller (61) of the at least one pair, a separate drive element that

- Is mechanically decoupled from a drive element or

- is coupled to the one drive element in such a way that the separate drive element is able to superimpose the rotation of the one drive element transmitted to the associated opening roller (61). Textile machine (1), comprising a device according to one of claims 8 to 13. Textile machine (1) according to claim 14, formed as

• Cleanser,

• Step cleaner or

• Feeder.