EP0185788A1 - Wire-feeding device for an insulated wire cutting and stripping apparatus - Google Patents

Abstract

1. Cable transporting device in an apparatus for cutting cables to length and insulating them, with pressure application wheels which, situated opposite one another, abut on the cable being transported, wherein the pressure application wheels are toothed-belt wheels (7 to 12), a first toothed belt (6) is guided over at least two first stationary-position toothed-belt wheels (10, 11), a second toothed belt (5) is guided over at least two second toothed-belt wheels (7, 8) opposite the first toothed belt, and the second toothed-belt wheels (7, 8) are arranged on a pressure plate (4) which is preloaded in the direction towards the first toothed-belt wheels (10, 11), and one first and one second toothed-belt wheel (8 and 11) are driven at the same circumferential speed, characterised in that the pressure plate (4) is connected pivotably to a carriage (14) whose carriage guide is disposed approximately at right angles to the direction of travel of the toothed belts (5, 6), and the pressure plate is connected at the two sides of the pivot point (13) with two pneumatic cylinder-and-piston units (15, 16).

Description

The invention relates to a cable transport device in a cable cutting and stripping device according to the preamble of claim 1.

In the automotive industry, a large number of cables of different lengths are required for the production of cable harnesses, which are stripped at both ends and provided with cable lugs.

Devices for the automation of these processes are already on the market. In a known device, the cable is first passed through a cable straightening unit from the roll between two guide wheels. This cable straightening unit consists of two opposing pressure rollers, between which the cable is pulled and thus aligned along the axial direction of the rollers. This is followed by an identical design of pinch rollers, the axes of which are offset by 90, so that the cable is also straightened in the other direction.

The cable straightening unit is followed by two measuring rollers, which are driven by the cable passing through and whose number of revolutions is a measure of the length of the cable passing through. The number of revolutions is fed to a control unit which can be set to specific cable lengths and which stops the cable transport in accordance with the set length and then actuates the cable cutting device.

This is followed by the cable transport unit, which is connected to a drive unit and which provides the train for transporting the cable. The known cable transport unit consists of two pressure rollers placed against each other, only one of which is driven and between which the cable to be transported is held. The treads are perforated to increase friction. The mutual contact pressure is applied via springs, but can also be set manually via a spindle. A disadvantage of this device is that because of the small contact surface of the transport pressure rollers on the cable, the cable insulation, particularly in the case of thin insulating layers, can be damaged. Cables with insulation damage, which are installed in a motor vehicle, are obviously a difficult source of interference to fix, since the cables are usually inaccessible in cable ducts. There is also a risk of short circuits and the resulting vehicle fire.

There is also a disadvantage in the one-sided drive of only one pressure roller, since the other pressure roller is only moved over the transported cable. With the high transport speeds and the constant start-up and braking processes, this leads to slippage, which on the one hand can contribute to the insulation being damaged and on the other hand leads to inaccuracies in the measurement process for the cable lengths. The cables are therefore usually cut a little longer than set by the machine, which leads to considerable additional consumption due to the large number of cut cables leads to entire cable lengths.

In a similar way as described above, the contact pressure on the cable straightening unit is set manually using a spindle or springs. Manual adjustment by the mostly unskilled operators is also problematic there, since this has to be carried out precisely in order to function properly. Pressure springs slow down over time and are temperature-dependent, so that no constant contact pressure can be achieved. When processing cables of different thicknesses, however, readjustment would have to be carried out in any case.

After the transport device, the cable runs freely and without a guide to the cutting and stripping device. In between, a high-voltage tester for insulation testing may also be installed. The cutting and stripping device consists of a unit that cuts the cable to the desired length after stopping, then moves it back a little in the direction of the transport unit, cuts the cable insulation there and then strips the insulation piece by moving it forward. This means that this unit moves back and forth operationally, thereby bending the cable freely and without guidance. This can lead to transport problems.

The object of the invention, in contrast, is to develop a cable transport device in a cable cutting and stripping device in such a way that the cable insulation is no longer injured and the setting of the contact forces can also be reproduced precisely in the cable alignment unit and can be carried out without readjustment. Transport disruptions should also be prevented.

This task is carried out in a generic cable transport device with the characteristic features of the An spell 1 solved.

According to claim 1, the pressure rollers are designed as toothed belt wheels in the cable transport device. One toothed belt is guided over at least two toothed belt wheels. A toothed belt arrangement is mounted on a pressure plate, which can be biased towards the other toothed belt arrangement. The two toothed belts are each driven by a toothed belt wheel so that they run at the same speed.

A major advantage of the arrangement according to the invention is that the cable to be transported is held between the two toothed belts for a relatively long distance. The contact pressure on the cable is thus also distributed over a relatively long cable area, so that no punctiform pressure points occur The measure that both toothed belts are driven also contributes to a gentle and precise cable transport, so that the cable is immediately transported on to the start of the transport unit at the contact surfaces on both sides. Shear forces that can lead to damage to the insulation and slip are practically excluded by this measure.

According to claim 2, further toothed belt wheels should be attached to each toothed belt as pressure rollers. As a result, a largely uniform contact pressure can be applied to the cable over a long distance. The other toothed belt wheels are expediently chosen to be smaller than the two end toothed belt wheels, since then the toothed belt engages only on one side and there are no problems with synchronous engagement on the other side. In addition, the smaller toothed belt wheels can be arranged close to one another, so that the contact points on the toothed belt are also close to one another in the desired manner. According to claim 3, the pressure plate, or the pressure rollers on the pressure plate is no longer pressed with the aid of a spindle or a spring, but with the aid of a pneumatic cylinder-piston unit in a particularly advantageous manner. The pneumatic pressure can be set precisely and reproducibly with the help of an integrated manometer. Since the pneumatic piston is flexible, irregularities in the cable thickness are absorbed and compensated for. When processing cables of different thicknesses, no readjustment or readjustment on the pressing device is necessary.

A further advantageous embodiment results from the features of claim 4 in that the pressure plate is rotatably connected to a slide whose slide guide is approximately perpendicular to the direction of travel of the toothed belt, and the pressure plate is connected on both sides of the pivot point to two pneumatic cylinder-piston units . When the pressure source is switched off, the pressure plate can be moved far out of the contact area over the carriage, so that the cable can be easily inserted by hand before starting. After the pressure has been applied, the pressure plate is pressed onto the slide on both sides of the pivot point. The pressure plate, and thus the toothed belt running on it, can perform oscillating movements around the pivot point, so that the transport device runs very evenly and compensates for all irregularities in the cable very well.

It is expedient to coat the outside of the toothed belt with a friction lining which has a certain flexibility, so that the cable is pressed into it somewhat and lies against a fairly large area (claim 5).

With the features of claim 6, a simple gear arrangement for driving the two toothed belts is specified, which consists of only four gear wheels, and that works for all common Kabej diameters without readjustment or exchange of gear wheels.

Claim 7 proposes to feed the previously freely guided cable in a flexible tube, in particular a spiral spring. This ensures safe onward transport.

For the reasons already mentioned above, it is also expedient and advantageous on the cable straightening unit to press the rows of rollers or the pressure plates against one another with the aid of pneumatic cylinder-piston units. This means that the cable can also be inserted by hand when the pressure is switched off. A constant, reproducible pressure can be achieved during operation (Claim 8).

Using an exemplary embodiment, the invention is described with further features, details and advantages.

• Figur 1 eine Seitenansicht der Kabeltransporteinheit
• Figur 2 einen Schnitt entlang der Linie A-A aus Fig. 1
• Figur 3 einen Schnitt entlang der Linie B-B aus Fig. 1
• Figur 4 einen vereinfacht gezeichneten Schnitt entlang der Linie C-C aus Fig. 3
• Figur 5 eine Seitenansicht einer Kabelrichteinheit.

Show it

• Figure 1 is a side view of the cable transport unit
• FIG. 2 shows a section along the line AA from FIG. 1
• FIG. 3 shows a section along the line BB from FIG. 1
• FIG. 4 shows a simplified section along the line CC from FIG. 3
• Figure 5 is a side view of a cable straightening unit.

In Figure 1, a cable transport device is shown, which consists essentially of a base plate 2, a support plate 3, a pressure plate 4 and two toothed belts 5 and 6. The toothed belt 5 runs on two end toothed belt wheels 7, 8 and is supported at the bottom by four smaller toothed belt wheels 9. The toothed belt wheels 7, 8, 9 are rotatably arranged on the pressure plate 4 and the toothed belt wheel 8 is driven.

The toothed belt 5 is opposite the toothed belt 6, the runs over the toothed wheels 10, 11 and is supported in the middle by smaller toothed belt wheels 12 upwards. The toothed belt wheel 11 is also driven in such a way that both toothed belts 5, 6 run at the same speed. The pressure plate 4 is attached to a carriage 14 via an axis 13, so that the pressure plate 4 can perform up and down movements and pendulum movements. Pneumatic cylinder-piston units 15, 16 are arranged on both sides of the pressure plate 4 and press the pressure plate 4 and thus the toothed belt 5 downward in the direction of the other toothed belt 6 when pressure is applied.

A cable 17 is clamped and guided between the two toothed belts 5, 6 and is to be transported from right to left. The cable 17 continues on the left side in a spiral spring 18, which is connected to a high-voltage tester 19 or directly to the cutting and stripping device. The high-voltage tester 19 for the insulation test moves operationally as shown with the arrows drawn below. The spiral spring 18 bends as shown in dashed lines.

With the two dashed circles 20, 21, the corresponding gear wheels are indicated, which lie behind the support plate 3 and are explained in more detail in Figure 4.

The arrangement of the pressure plate 4 on the slide 14 via the axis 13 can be seen in FIG. Furthermore, the toothed belt 5 and 6 and the cable 17 guided between them are drawn in cross section.

FIGS. 3 and 4 show the gear arrangement for driving the toothed belts 5, 6. The toothed belt wheels 8 and 11 are firmly connected to gear wheels 22 and 23 via common axes. The gear wheels 22, 23 are driven by the gear wheels 20, 21. The gear arrangement for this is shown in FIG. 4. The gears 20, 21, 22 are attached to the support plate 3 and are in constant engagement. The gear 20 is connected via its elongated axis 24 to a drive, not shown. The gear 23 is arranged on the displaceable pressure plate 4. If the pressure plate 4, for example when inserting the cable 17, is shifted upward, the gears 21 and 23 are not in engagement. In operation, however, the gear 23 is pushed as far downwards in the area of the gear 21 that both gears are in engagement for all common cable sizes.

The arrangement shown has the following function: To insert the cable 17, the pressure in the cylinder-piston units 15, 16 is switched off and the pressure plate 4 on the carriage 14 is shifted upwards. This leaves a large gap between the toothed belts 5, 6, in which the cable 17 can be conveniently inserted. For operation, pressure is then brought into the cylinder-piston units 15, 16, as a result of which the toothed belt 5 is pressed against the toothed belt 6 via the cable 17. At the same time, the gear wheel 23 meshes with the driven gear wheel 21. During transport, the cable is gently moved between the contact surfaces on the toothed belts 5, 6, irregularities in the cable diameter being compensated for by the oscillating suspension of the pressure plate 4 and the resilient pneumatic pressure load.

FIG. 5 shows a cable straightening unit 25 which is arranged in front of the unit from FIG. 1. The cable straightening unit consists of two rows of rollers 26, 27, of which the row of rollers 27 is arranged on a pressure plate 28. The pressure plate 28 is connected to a pneumatic cylinder-piston unit 29, so that at brought pressure, the row of rollers 27 is pressed against the row of rollers 26. After the rows of rollers 26, 27 there are two further rows of rollers, the axes of which are offset by 90 ° and of which only one row of rollers 30 can be seen in FIG. These rows of rollers are also pressed together pneumatically. In an alternative embodiment, the dashed circles 31, 32 indicate two pneumatic cylinder-piston units for applying the contact pressure.

To insert the cable 17, the pressure in the cylinder-piston units is switched off, as a result of which the rows of rollers can be moved apart and the cable 17 can be inserted easily. The contact pressure can be set precisely and reproducibly with the help of a manometer.

In summary, it is stated that the innovation provides a cable transport device which, with a simple construction and simple handling, enables problem-free cable transport without damaging the cable insulation.

Claims (14)

1. Cable transport device in a cable cutting and stripping device with pressure rollers that lie against each other on the cable to be transported and one of which is driven, characterized, that the pressure rollers are toothed belt wheels (7 to 12). that a first toothed belt (6) is guided over at least two first stationary toothed belt wheels (10, 11), that a second toothed belt (5) is guided relative to the first toothed belt (6) via at least two second toothed belt wheels (7, 8), and the second toothed belt wheels (7, 8) are mounted on a pressure plate (4) in the direction of the first toothed belt wheels (10, 11) are biased, and that a first and second toothed belt wheel (8 and 11) is driven at the same peripheral speed. 1. Cable transport device in a cable cutting and stripping device with pressure rollers that lie against each other on the cable to be transported, the pressure rollers being toothed belt wheels (7 to 12), a first toothed belt (6) is guided over at least two first stationary toothed belt wheels (10, 11), A second toothed belt (5) is guided relative to the first toothed belt (6) via at least two second toothed belt wheels (7, 8), and the second toothed belt wheels (7, 8) are mounted on a pressure plate (4) which is directed towards the first Toothed belt wheels (10, 11) is biased, and a first and second toothed belt wheel (8 and 11) are driven at the same peripheral speed, characterized, that the pressure plate (4) is rotatably connected to a slide (14), whose slide guide is approximately perpendicular to the direction of travel of the toothed belt (5, 6), and the pressure plate on both sides of the pivot point (13) with two pneumatic cylinder-piston units (15, 16) is connected. 2. Cable transport device according to claim 1, characterized in that the first and / or second toothed belt wheels of two end, larger toothed belt wheels (7, 8; 10, 11) and intermediate smaller toothed belt wheels (9; 12) are formed and the larger and smaller ones Engage the toothed belt wheels (7 to 12) in the contact direction in the toothed belts (5, 6) and press them against the cable. 3. Cable transport device according to claim 1 or 2, characterized in that the toothed belt outside is coated with a friction lining, in particular a Teflon lining. - 4. Cable transport device according to one of claims 1 to 3, characterized in that a gear is provided for driving the toothed belt wheels (8, 11), which consists of a first gear wheel connected to a motor drive (20), a second gear wheel (22) which is constantly engaged with the first gear wheel (20) and at the same time is axially fixed to a large, stationary toothed belt wheel (11), a third gear wheel (21), the axis of which is offset in the direction of displacement of the pressure plate (4) with respect to the axis of the first gear wheel (20), both gear wheels (20 and 21) being constantly engaged, from a fourth gear wheel (23) which is axially firmly connected to a large toothed belt wheel (8) on the pressure plate (4) and which when the 2. cable transport device, according to claim 1, characterized in that the first and / or second toothed belt wheels of two end, larger toothed belt wheels (7, 8; 10, 11) and intermediate smaller toothed belt wheels (9; 12) are formed and the larger and engage smaller toothed belt wheels (7 to 12) in the direction of contact in the toothed belts (5, 6) and press them against the cable. 3. Cable transport device according to claim 1 or claim 2, characterized in that the pressure plate (4) with the aid of a pneumatic cylinder-piston unit (15, 16) is biased. 4. Cable transport device according to one of claims 1 to 3, characterized in that the pressure plate (4) is rotatably connected to a slide (14) whose slide guide is approximately perpendicular to the direction of travel of the toothed belt (5, 6), and the pressure plate on both sides of the Pivot point (13) is connected to two pneumatic cylinder-piston units (15, 16). 5. Cable transport device according to one of claims 1 to 4, characterized in that the toothed belt outside is coated with a friction lining, in particular a Teflon lining. 6. Cable transport device according to one of claims 2 to 5, characterized in that a gear is provided for driving the toothed belt wheels (8, 11), which consists of a first drive gear connected to a motor drive (20), a second gear wheel (22) which is constantly engaged with the first gear wheel (20) and at the same time is axially fixed to a large, stationary toothed belt wheel (11), a third gear wheel (21), the axis of which is offset in the direction of displacement of the pressure plate (4) with respect to the axis of the first gear wheel (20), both gear wheels (20 and 21) being constantly engaged, from a fourth gear wheel (23), which is axially firmly connected to a large toothed belt wheel (8) on the pressure plate (4) and which, when the pressure plate (4) is moved into the use position, ie for cable transport, into the third gear wheel (21) intervenes. 7. Cable transport device according to one of claims 1 to 6, with a stripping device and / or cable insulation measuring device arranged in a manner known per se after the transport device, characterized, that the cable (17) is guided between the transport device (1) and the stripping and / or cable insulation measuring device in a flexible tube (18), in particular a spiral spring. 8. Cable transport device according to one of claims 1 to 6, with a cable straightening unit known per se, consisting of a first unit with a row of rollers and pressed second row of rollers and an identically constructed second unit in the cable pulling direction behind the first unit, the roller axes of which are at 90 ° are offset characterized, , that the second rows of rollers (27, 30) are mounted on pressure plates (28) which are pressed against the first rows of rollers (26) via pneumatic cylinder-piston units (29, 31, 32). Pressure plate (4) engages in the use position, ie for cable transport, in the third gear wheel (21). 5. Cable transport device according to one of claims 1 to 4, with a stripping device and / or cable insulation measuring device arranged in a known manner after the transport device, characterized, that the cable (17) is guided between the transport device (1) and the stripping and / or cable insulation measuring device in a flexible tube (18), in particular a spiral spring. 6. Cable transport device according to one of claims 1 to 5, with a cable straightening unit known per se, consisting of a first unit with a row of rollers and a second row of rollers pressed against it and an identically constructed second unit in the cable pulling direction behind the first unit, the roller axes of which are at 90 ° are offset characterized, that the second rows of rollers (27, 30) are mounted on pressure plates (28) which are pressed against the first rows of rollers (26) via pneumatic cylinder-piston units (29, 31, 32).

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