WO2021078485A1

WO2021078485A1 - Spinning preparation machine

Info

Publication number: WO2021078485A1
Application number: PCT/EP2020/077460
Authority: WO
Inventors: Armin Leder; Dieter Wirtz
Original assignee: TRüTZSCHLER GMBH & CO. KG
Priority date: 2019-10-23
Filing date: 2020-10-01
Publication date: 2021-04-29
Also published as: CN114651094B; CN114651094A; EP4048832A1; DE102019128620A1

Abstract

The invention relates to a spinning preparation machine, in particular a carding machine (K), having an inlet side for fibre flakes, which are fed to a rotating drum (4) by means of rollers, and, between fixed carding elements and circulating flat bars (14) and the drum (4), are opened into individual fibres, oriented and cleaned, and the resultant fibrous web is transferred from the drum (4) to a doffer (5), downstream of which at least one take-off unit for the further processing or storage of the fibrous web (19) is arranged, comprising a machine controller (26) configured to process and regulate at least the production data. The invention is characterized in that the spinning preparation machine has at least one pilot controller (24) configured to process data from sensors and/or drives independently of the machine controller (26) and to control the drives connected to the pilot controller (24).

Description

Title: Spinning Preparation Machine

description

The invention relates to a spinning preparation machine, in particular a card or card, with an inlet side for fiber flocks, which are fed to a rotating drum by means of rollers, and between fixed carding elements and rotating flat bars and the drum are dissolved, aligned and cleaned down to the individual fiber, and the resulting Fiber web is transferred from the drum to a doffer, which is followed by at least one take-off unit for further processing or depositing the fiber web, comprising a machine control that is designed to process and regulate at least the production data.

According to the prior art in the field of textile technology, in a spinning preparation machine (e.g. card or card) for treating cotton, man-made fibers or the like, sensors for monitoring, for example, the temperature of various components, the carding gap, drive or setting motors, as well as the mass throughput of fibers to be used. The data from the sensors are fed into the card's control system via electrical lines, where they are evaluated and used to adjust the card, either by informing the operator of an expected change in setting via a signal, or by a control or regulating circuit automatically making a change. The electrical lines are routed from all points on the card into the control cabinet, where they are adapted to terminal strips by means of plugs and from there connected to the inputs and outputs of the control system. The switchgear cabinet is usually arranged on the back of the card in the area of the feed chute, so that in total several hundred meters of electrical lines quickly come together over the number of sensors, actuators and drive motors. Since some of these electrical lines still transmit the signals in analog form, they must be shielded from the high-frequency motor lines that are subjected to high currents. In addition, the controller has to process more and more of these input / output signals at the same or shorter intervals. In the event of system errors, it is very time-consuming to check all connections, lines and the connected sensors. The effort involved in laying these electrical lines and shielding them against high-frequency currents is very expensive. Accordingly, the invention is based on the object of developing a spinning preparation machine in such a way as to reduce the expenditure for laying and shielding these electrical lines and the expenditure for eliminating possible errors.

The invention solves the problem posed by a device with the features specified in claim 1. Advantageous developments of the invention are defined in the dependent claims.

A device according to the present invention is used in a spinning preparation machine, in particular in the form of a card or card, with an inlet side for fiber flocks, which are fed to a rotating drum by means of rollers, and dissolved between fixed carding elements and rotating flat bars and the drum down to the individual fiber, aligned and cleaned, and the resulting fiber web is transferred from the drum to a buyer, which is followed by at least one take-off unit for further processing or depositing the fiber web, comprising a machine control that is designed to process and regulate at least the production data.

The invention includes the technical teaching that the spinning preparation machine has at least one pilot control which is designed to process data from sensors and / or drives independently of the machine control and to control at least the drives connected to the pilot control. In particular, the sensors and drives arranged in the local area are connected to the pilot control, so that the cabling can be carried out more easily and less susceptible to interference. The sensors and drives that are relevant for the respective assembly are referred to as being located in close proximity, for example the sensors and drives that are arranged on and / or in the area of the assembly (drum, revolving cover, side plates), or that are e.g. a certain function (adjustment of the carding gap, or distance between drum and doffer, or foreign part or nep detection behind the doffer, etc.) are essential. This also makes it easier to identify possible errors in the control, since the data communication between the pre-control and the machine control can be restricted.

In an advantageous development of the invention, the at least one pilot control can be arranged in the region of the drum on at least one side plate. In this way, for example, the data from the temperature sensors, which are arranged on the side plate or on or in the area of the drum, can flow into the pilot control. The pilot control can preferably be arranged in the area of the axis of rotation of the drum on the side plate. This also results in short cable lengths and simple cabling. The at least one pilot control can preferably process all relevant data from sensors and drives for carding gap control. This means that the pre-control can be operated independently of the production data of the machine control, which relieves the machine control and enables, for example, the use of different processors.

For this purpose, the at least one pre-control can have at least one processor for processing data. The processor can be programmed independently of the machine control and, for example, combined with an additional memory to form an electronic assembly. This means that modular sub-functions can be programmed and changed in the spinning preparation machine according to customer requirements, regardless of the basic function stored in the machine control.

Advantageously, the pilot control can communicate with the machine control using a BUS system. The BUS system can consist of a cable that is not susceptible to interference, which is very easy to lay. The pre-control can preferably be programmable independently of the machine control. This means that a software update for partial functions is possible regardless of any intervention in the machine control.

In an advantageous embodiment, the spinning preparation machine can have at least two pilot controls, each pilot controller being designed to process the data from sensors and drives for one or more separate functional areas and to control the associated drives. For example, a separate pilot control can be arranged on each side plate, which processes the temperature and carding gap data separately for each side of the spinning preparation machine.

The functional areas can be designed as a carding gap control for each card side, or as a distance control between at least two components or as a quality feature of the fiber web.

The communication between the pilot control and the machine control can preferably be limited to the exchange of setpoints and actual values for the input of production data and / or to fault or readiness messages. The processing of the data from sub-functions takes place independently of one another and accelerates the functionality of the spinning preparation machine. Further measures improving the invention are shown in more detail below together with the description of a preferred exemplary embodiment of the invention with reference to the figures.

1 shows a schematic side view of a spinning preparation machine in the form of a card, in which the device according to the invention is used,

2 shows a perspective illustration of a side plate of a card.

Preferred embodiments of the spinning preparation machine according to the invention and the method are explained below with reference to FIGS. The same features in the drawing are each provided with the same reference numerals. At this point it goes without saying that the drawing is only shown in a simplified manner and in particular without a scale.

The spinning preparation machine can be a card K, which is shown in FIG. 1 in a schematically simplified side view. Alternatively, the spinning preparation machine can also be designed as a carding machine (not shown). Flocks of fiber are fed via a shaft to a feed roller 1, a feed table 2, via several lickerins 3a, 3b, 3c to the drum 4 or the tambour. On the drum 4, the fibers of the fiber flocks are parallelized and cleaned by means of stationary carding elements (flat rods) 14 arranged on a revolving flat 13 rotating around flat guide rollers 13a, 13b. The resulting fiber pile is then conveyed via a doffer 5, a doffing roller 6 and several nip rollers 7, 8 to a fleece guide element 9, which transforms the fiber pile with a pile funnel 10 into a sliver, which is sent via take-off rollers 11, 12 to a subsequent processing machine or a Can 15 is passed with can stick 16. The center point (or the bearing axis) of the drum 4 is denoted by M. The arrow A indicates the working direction in relation to the fiber material or fiber fleece F. The directions of rotation of the rollers are indicated in FIG. 1 by curved arrows, the arrow 4b indicating the direction of rotation of the drum 4. The direction of rotation of the revolving flat 13 in the carding position is denoted by C, and the direction of its return transport is denoted by D. The area of the card K where the sliver emerges and is deposited in the can 15 is referred to as the front of the card K. The switchgear cabinet 25 is usually arranged on the rear side of the card K, that is to say the area in which the fiber flocks are fed. The machine control 26 of the card K can also be in the switch cabinet 25 or in the area of the switch cabinet 25 be arranged and communicates with an input display, not shown here, which can be arranged laterally in the area of the sliver exit from the card K. The machine control 26 can, however, also be arranged with the input display in a common housing. In the machine control 26 of the card K, all data important for the production of the card are processed, for example the flock feed, the speed of the drive motors, the mass control of the fibers to be processed, the air pressures applied, the can fill level and all options for wear-relevant components. The machine control 26 can communicate with a central control of the spinning preparation, so that the data from all machines of the spinning preparation converge there and a quality control and presetting of the various machine types can take place.

The at least one pilot control 24 according to the invention is preferably arranged in the area of the drum 4, for example on a side plate 17 or in the area of the axis of rotation of the drum 4, since this is the central point for bringing together the electrical lines to the sensors and actuators that are connected to or are arranged around the drum 4. Intelligent preprocessing and compilation of the data from the sensors located in the local area takes place via the at least one pilot control 24, so that the electrical lines are made shorter and the sensitivity to interference is significantly reduced. This has the advantage that the signals arriving here are preprocessed independently of the machine control 26, so that the machine control 26 is relieved of the load. For this purpose, the pilot control 24 can have an electronic assembly that is designed as hardware (processor and memory) with which the signals from the sensors and actuators can be preprocessed, or alternatively as a high-performance processor to be configured by software. In particular, the pilot control 24 is designed to process all relevant data for regulating the carding gap, for example various temperature signals from different components in the machine, various contact signals of the drum 4 with the adjacent components such as lickerins, carding and separating elements, rotating flat rods 14 and / or Pick-up 5, counting signals from the revolving cover 13 and the drum 4, and / or control signals and

Feedback on the motorized setting of the V-ledge and thus the carding gap. The pilot control 24 can be designed to process the signals permanently, so that carding gap regulation independent of the machine control 26 is possible. The contact signals can be evaluated at high frequency in the pre-control 24 in order, for example, to calibrate and set the carding gap between the clothings of the revolving flat 13 and the drum 4. As an alternative or in addition, the contacts of elements with the drum 4 outside the revolving cover 13 can be recorded and processed in the pilot control 24. The control circuit of the actuators of the V-ledge ensures that a pre-selected carding gap is set and kept constant. The data from the various temperature sensors are also included, so that the carding gap can be kept constant in the event of a temperature change on the machine. The communication of the pilot control 24 with the machine control 26 can be limited to an exchange of setpoint and actual values for the input, to fault or readiness messages and can take place via a digital BUS system. This BUS system can consist of a cable that is not susceptible to interference and can have several wires. The combination of the functions in the local vicinity of the sensors gives the operator of the machine the opportunity to carry out troubleshooting and control in a more targeted manner without having to laboriously identify the associated assemblies in the control cabinet. ^LEDs can be arranged, which indicate the basic function of each module and its operability to the digital bus node.

According to FIG. 2, the pilot control 24 is arranged on a side plate 17 in the area of the axis of rotation of the drum 4, for example. The pilot control 24 can expediently also be arranged at another central location in the region of the drum 4. The data from the actuators and sensors on the temperature of the side plates 17a, the ambient temperature 18, the material inlet monitoring 19, the temperature of the drum cover 21 and the carding gap adjustment 22 are fed to the pilot control 24 via various electrical lines 23. In the event of an electrical contact between the clothing of the revolving flat 13 and the drum 4, an electrical short circuit is passed as a signal via at least one of here four contact arcs 20 on each side of the card to the pilot control 24. Software can be uploaded to the pre-control 24, in particular with the automatic carding gap setting, which can determine the location of the contact more precisely by means of statistical evaluation when the clothing tips contact. In this way, the pilot control 24 can be adapted in a targeted manner to specific requirements of the card operation without having to intervene in the central machine control.

A plurality of pilot controls 24 can advantageously also be used, for example in order to separately evaluate the sensor data for setting and keeping the carding gap constant on each side of each side plate 17 of the card. This allows one-sided temperature load across the working width of the card, the wedge strips on both sides of the drum 4 are controlled independently in order to adjust the carding gap. The two pre-controls 24 can communicate with one another independently of the machine control and forward their data to the machine control 26 independently of one another. This then also contributes to easier installation and troubleshooting.

A further pilot control 24 can be arranged in the area of the doffer 5, on the one hand to regulate the spacing of the clothing between the doffing device 5 and the drum 4, and on the other hand also to control the data from the nep sensor or sensors which are arranged in the area of the doffing device 5, preprocessing. As a result of the technological advancement of textile machines, more and more sensors and actuators are inevitably used, so that the precontrol 24 according to the invention can be used to systematically preprocess the signals and thus reduce the complexity and susceptibility of the overall system to errors. The installation of the sensors and actuators is simpler, cheaper and less prone to errors, since the electrical lines from the area of the drum 4 or the side plate 17 only have to be connected to the pilot control 24. In contrast to the existing and available BUS systems of the supplier industry, the BUS system used in the pilot control 24 can be configured individually by software in order to be able to carry out any conceivable control task, even of high complexity, independently of the machine control 26.

Reference number:

K card

1 feed roller

2 dining table

3a, 3b, 3c lickerin roller

4 drum

4b direction of rotation (of drum 4)

5 customers

6 scraper roller

7, 8 nip roller

9 Fleece guide element

10 pile funnels 11, 12 take-off rollers

13 revolving cover 13a, 13b cover pulleys

14 flat bars

15 jug

16 jug stick

17 side plate

17a Sensor temperature side plate

18 Ambient temperature sensor

19 Sensor material inlet monitoring

20 contact sheets

21 Sensor temperature cover drum

22 Carding gap adjustment sensor

23 management

24 feedforward control

25 control cabinet

26 Machine control

A working direction

C Direction of rotation (of revolving cover 13)

D Return transport direction (of the flat rods 14)

M center point or bearing axis (of drum 4)

Claims

1. Spinning preparation machine, in particular a card (K) or card, with an inlet side for fiber flocks, which are fed to a rotating drum (4) by means of rollers, and dissolved between fixed carding elements and rotating flat bars (14) and the drum (4) down to the individual fiber , aligned and cleaned, and the resulting fiber web is transferred from the drum (4) to a doffer (5), which is followed by at least one take-off unit for further processing or depositing the fiber web (19), comprising a machine control (26) which is designed to process and regulate at least the production data, characterized in that the spinning preparation machine has at least one

Pre-control (24) which is designed to process data from sensors and / or drives independently of the machine control (26) and to control at least the drives connected to the pre-control (24).

2. Spinning preparation machine according to claim 1, characterized in that the at least one pilot control (24) in the region of the drum (4) on at least one

Side plate (17) is arranged.

3. Spinning preparation machine according to claim 2, characterized in that the at least one pilot control (24) processes all relevant data from sensors and drives for carding gap control.

4. Spinning preparation machine according to claim 1, characterized in that the at least one pilot control (24) has at least one processor for processing data.

5. Spinning preparation machine according to one of the preceding claims, characterized in that the pilot control (24) communicates with a BUS system with the machine control (26).

6. Spinning preparation machine according to one of the preceding claims, characterized in that the pilot control (24) is programmable independently of the machine control (26).

7. Spinning preparation machine according to claim 1, characterized in that the spinning preparation machine has at least two pilot controls (24), each pilot control (24) being designed to process the data from sensors and drives to one or more separate functional areas and to control the associated drives.

8. Spinning preparation machine according to claim 7, characterized in that the functional areas are designed as a carding gap control for each card side, as a distance control between at least two components or as a quality feature of the fiber web.

9. Spinning preparation machine according to one of the preceding claims, characterized in that the at least one pilot control (24) is designed to process the data from the sensors and drives arranged in close proximity.

10. Spinning preparation machine according to one of the preceding claims, characterized in that the communication of the pilot control (24) with the machine control (26) is limited to the exchange of setpoint and actual values for the input of production data and / or to fault or readiness messages.