WO2012171836A1

WO2012171836A1 - Tensioning unit for transporting filaments

Info

Publication number: WO2012171836A1
Application number: PCT/EP2012/060689
Authority: WO
Inventors: Rolf Schröder
Original assignee: Trützschler Nonwovens Gmbh
Priority date: 2011-06-11
Filing date: 2012-06-06
Publication date: 2012-12-20
Also published as: CN103635406B; EP2718215A1; EP2718215B1; CN103635406A

Abstract

The invention relates to a tensioning unit for a fibre line, and consisting of a number of driven rollers about which the filaments are guided, one of these rollers interacting with an adjusted counter roller, and the filaments running through the roller gap that is formed in this manner. According to the invention, the rollers (Z1, Z2, Z3, Z4, Z5) and their drive (AM) are received in a transportable rack unit (G).

Description

Train for the transport of filaments

The invention relates to a train according to the preamble of claim 1.

Tractors of the generic type are used in fiber lines between individual processing stations application. By driven rollers around which the filaments bundled into cables are guided, the necessary to promote the filaments tensile forces are applied.

The invention is therefore based on a train for the transport of filaments, in particular carbon filaments, consisting of a number of driven rollers around which the filaments are guided, wherein one of the rollers cooperates with an employee counter-roller and the filaments run through the nip formed in this way. The filaments are endless fibers. A strand or a bundle of filaments forms a cable.

Object of the present invention is to improve a generic device.

This problem is solved by the features of the device claim. Advantageous developments of the invention will become apparent from the dependent claims. According to the invention, it is provided that the rollers and their drive are accommodated in a transportable frame unit. This offers the advantage that the train can be used with identical construction at a variety of locations within a fiber line. The train may be equipped with a different number of driven rollers. The entry and exit serving rollers are not driven.

The driven rollers are driven according to a preferred embodiment of the invention by a drive via a traction means (chain). The drive further includes the electrical control and the power supply, so that the train of the invention after the mechanical installation only needs to be connected to the network and connected to the control of the fiber line. The preferably mounted on top of the frame drive does not hinder accessibility to the individual rollers of the train. Alternatively, the driven rollers can each be assigned a single motor, so that the rollers can be driven separately from each other. Also, in this case, the individual motors can be controlled separately. The motors can be controlled, for example, by controlling the torques of the respective motors.

The non-driven rollers of the inlet and / or outlet are preferably arranged in height adjustable on the frame, so that the height of the cable run can be adjusted. This is particularly advantageous when the train according to the invention is upstream or downstream of a furnace and the filaments combined into cables are in particular carbon filaments. Such devices usually have very narrow input gaps for the cables to be treated, by the adjustability of the cable run can be made to adapt to the particular circumstances.

A further embodiment of the invention provides that the non-driven input and / or output roller is coupled to a measuring system for detecting the tension present in the incoming or outgoing cable. This is done for example by a load cell, which is mounted between the frame and the storage of the respective roller. A measuring system designed in this way allows the force exerted by the cable on the roller to be taken into account Running directions are determined in the cable traction. These values are used to monitor the operation and in particular to avoid too ^high voltages during the startup of the system, since here the system parts connected in series are to be operated in a coordinated manner with respect to each other in their speed. This has the advantage that filmmentrisse be avoided.

Another preferred embodiment of the invention provides that at least one of the driven pull rolls is at least partially connected, that is to say provided with a cover surrounding the roll surface at least in a partial circumferential region. A draw roller is a roller of the train. The cup-shaped covers serve to protect people and prevent hazards due to incoming column, especially in the area between the running on a draw roller cable and the corresponding rotating roller surface.

The cover is preferably associated in the partial circumference of the roller surface of the tension roller, around which the filaments bundled in cables are not wound in normal operation. In normal operation means that there is no Filamentriss. In the case of a filament tear, the torn off filaments wrap around the roll (s) and, in this case, also the partial circumference of the roll surface of the roll is wrapped with the cables in which the cover is arranged.

In the case of a roll, that is, when tearing filaments in the cable and looping continuously around the rotating roller, the tension train must be stopped and the cable strand wound around the roller must be removed. This is usually done with a knife, which is pulled by an operator in the axial direction over the roll surface.

With a roll width of two or more meters, this is only possible with great difficulty. The operator must move within the rack area to an appropriate position and sever the wound wire harness. Here, a further embodiment of the invention provides a remedy, which provides a running in the axial direction of the respective roller and parallel to this guide for a cutting device. The leadership is designed so that the Cutting device by means of the guide to the roll surface of the roll guide and / or preferably in the axial direction along the roll surface of the roll is feasible.

The cutting device is, for example, a knife attached to an extension, which is pulled by the operator along the guide over the roll surface of the roll. In this case, the cutting device is moved manually. Alternatively, however, the cutting device can also be actuated automatically. There may be provided a drive, for example an electrically driven drive, which has a cutting device, e.g. a knife, moved by means of the guide to the roll surface and / or preferably moved in the axial direction along the roll surface. The electric drive can be actuated for example by an operator as soon as the operator determines that it has come to a winding.

Preferably, this guide, if it is formed in the form of a slot in a roll verschalenden the cover.

In summary, the following developments of the invention are provided:

- The drive is arranged in an upper part of the frame unit.

- The drive is coupled via a traction means with the driven tension rollers.

- The traction means is designed as a chain and the tension rollers are driven by sprockets wrapped around the chain.

- At least one of the draw rollers is associated with a extending over its length and a partial circumference covering part cover.

- At least one of the tension rollers is associated with an axially extending guide for a cutting device. - The guide is designed such that the cutting device by means of the guide to the roll surface and / or preferably in the axial direction ent ^¬ long the roll surface of the tension roller is feasible.

- The guide is formed by a running in the axial direction of the draw roller gap of the partial cover.

- The train has at least one of the inlet and / or outlet of the cable ^¬ nende, non-driven inlet and / or outlet roller.

- The inlet and / or outlet roller is mounted in height adjustable on the frame unit.

- The inlet and / or outlet roller is mounted on the frame unit via a force measuring system.

Furthermore, the explanation of exemplary embodiments with reference to the drawings.

It show schematically

2 shows the course of the cables, FIG. 3 shows the drive of the rollers, FIG.

4 shows a further embodiment of the train according to the invention, FIG. 5 shows a side view of the train of FIG. 4,

FIG. 6 shows a partial cover according to the invention of a draw roller,

FIG. 7 shows a side view of the draw roller with partial cover from FIG. 6. Figure 1 shows a train according to the invention in a perspective view. A common and consisting of four vertical posts together with cross members frame G carries each a non-driven inlet and outlet roller EW, AW and three driven tension rollers ZI, Z2, Z3. The middle of the tension rollers Z2 cooperates with a counter roller GW, which is adjustably mounted at its two ends and is adjustable relative to the tension roller Z2. The adjustment of the counter roll GW to the tension roller Z2 is done by motor or pneumatically by an associated drive GAl, GA2, which engage the bearings of the counter roll GW and thus enables an exact parallel position of the rollers GW, Z2.

As shown in FIG. 2, the filaments F, preferably carbon filaments, which are bundled into cables, run into the pulling mechanism via an inlet roller EW. FIG. 2 shows the arrangement of the rollers EW, ZI, Z2, Z3, GE, AW; the conveying direction of the filaments F is indicated by the arrows. This also applies to the other figures. The incoming on the top of the inlet roller EW filaments F are deflected by the inlet roller EW down and run around the first, lying below draw roller ZI. From there, the filaments F bundled into cables run to the above lying draw roller Z2 and through the gap formed with the counter roll GW. The filaments F bundled into cables now run down again to the third drawing roller Z3 and then to the outlet roller AW located at the same height as the inlet roller EW. About this exit roller AW leave the bundled to cables filaments F the train again.

The wrapping of the inlet and outlet rollers EW, AW through the filaments F bundled into cables is less than 90 °. The looping of the draw rollers ZI, Z2, Z3 through the bundled filaments F is substantially 180 °. This results in a good transmission of the drive torque of the rollers ZI, Z2, Z3 on the bundled filaments F.

As shown in Figures 1 and 2, the arrangement of the rollers EW, ZI, Z2, Z3, AW symmetrical to each other, resulting in a high variability in setting up the train within a fiber strand. Several trains of one type can thus be installed at different positions of the fiber line, for example between the oxidation furnaces of a carbon fiber plant. About anchors to the posts of the frame G, the train is fixed in the intended position on the ground. The frame G or the frame unit is transportable.

FIG. 3 shows the drive of the rollers EW, ZI, Z2, Z3, AW. On one side, the draw rollers ZI, Z2, Z3 have sprockets Rl, R2, R3, around which a chain K runs as traction means. The chain K is also guided around a deflection wheel UR and is driven by a drive wheel AR coupled to a drive motor AM.

Figures 4 and 5 show a further embodiment of the train according to the invention, which has a total of five driven draw rollers ZI, Z2, Z3, Z4, Z5 between the arranged at different heights and an outlet rollers EW, AW.

In the area of the outlet roll AW, a cable guide KF is arranged for separating the filaments F bundled into cables. The cable guide KF is a multiplicity of pins mounted on a crosspiece which engage in the group of filaments F like the teeth of a comb and so lead the cables.

FIG. 6 shows the partial cover TA according to the invention of a drawing roller, namely of the draw roller Z3 according to the exemplary embodiment as shown in FIG. Extending over the entire width of the draw roller Z3 is a shell-shaped sheet-metal part TA surrounding the roll in a partial circumference and adapted to the shape of the roll surface, which has a gap-shaped opening as a guide FTA for a cutting device SV in a central region. The sheet-metal part TA consists of two shell parts which, in the region forming the gap of the guide FTA, have beveled limbs which run parallel to one another.

The cutting device SV is a knife and can be manually or automatically movable. The holder of the cutting device SV is not shown. The cutting device can preferably be arranged in the radial direction SR of the roller in the direction of rotation. tion of the roll surface to be moved, wherein the cutting device SV can be guided in the direction of the roll surface by means of the guide FTA.

Furthermore, as can be seen from FIG. 7, the cutting device SV can be moved in the axial direction of the roller, wherein the cutting device can also be guided with this movement by means of the guide FTA. FIG. 7 is the side view of FIG. 6, but the filaments F are not shown in FIG. Alternatively, the cutting device could also have a length corresponding to the length of the guide FTA. In this case, the cutting device would only have to be moved in the radial direction in the direction of the roll surface.

When film breaks occur during operation, the broken filaments are wound on the draw roll. To remove these from the roller, the filaments must be cut off. For this, the cutting device is used.

LIST OF REFERENCE NUMBERS

G frame, posts, cross member

EW infeed roller

AW outlet roller

ZI pull roller

Z2 tension roller

Z3 draw roller

Z4 tension roller

Z5 draw roller

F filaments, cables

GW counter roller (to pull roller Z2 or Ζ ·

GA1, GA2 Drive adjustment Counter roller GW

AM drive motor

K chain

AR drive wheel

UR diverter wheel

Rl sprocket draw roller ZI

R2 sprocket pull roller Z2

R3 sprocket pull roller Z3

R4 sprocket pull roller Z4

R5 sprocket draw roller Z5

KF cable routing

TA partial cover (draw roller), sheet metal part

FTA guide, split in partial cover

SV cutting device

SR radial direction

SA axial direction

Claims

claims

1. A train for the transport of filaments, consisting of a number of driven rollers around which the filaments are guided, one of the rollers cooperates with an employee counter-roller and the filaments run through the nip formed, characterized in that the rollers (ZI , Z2, Z3, Z4, Z5) and their drive (AM) are accommodated in a transportable frame unit (G).

2. Zugwerk according to claim 1, characterized in that the drive (AM) in an upper part of the frame unit (G) is arranged.

3. Zugwerk according to claim 1 or 2, characterized in that the drive via a traction means (K) with the driven tension rollers (ZI, Z2, Z3, Z4, Z5) is coupled

4. Zugwerk according to claim 3, characterized in that the traction means is designed as a chain (K) and the draw rollers (ZI, Z2, Z3, Z4, Z5) by the chain looped sprockets (Rl, R2, R3, R4, R5 ) are driven.

5. Zugwerk according to any one of the preceding claims, characterized in that at least one of the draw rollers (ZI, Z2, Z3, Z4, Z5) is associated with a extending over its length and a partial circumference covering part cover (TA).

6. Train according to one of the preceding claims, characterized in that at least one of the draw rollers (ZI, Z2, Z3, Z4, Z5) is associated with an axially extending guide (FTA) for a cutting device.

7. Zugwerk according to claim 5 and 6, characterized in that the Füh- tion (FTA) is formed such that the cutting device by means of the guide to and / or preferably in the axial direction along the roll surface of the tension roller is feasible.

8. Zugwerk according to one of claims 5 to 7, characterized in that the guide (FTA) by a in the axial direction of the draw roller (ZI, Z2, Z3, Z4, Z5) extending gap of the partial cover (TA) is formed.

9. Zugwerk according to any one of the preceding claims, characterized in that the train has at least one input and / or outlet of the cable (F) serving, non-driven input and / or outlet roller (EW, AW).

10. Zugwerk according to claim 8, characterized in that the input and / or outlet roller (EW, AW) in height adjustable on the frame unit (G) is mounted.

11. Zugwerk according to claim 8, characterized in that the input and / or outlet roller (EW, AW) via a force measuring system to the frame unit (G) is mounted.