FI77631C - TRANSPORTANORDNING FOER KABELFRAMSTAELLNINGSAUTOMAT. - Google Patents

Description

1 77631

Transport device for a cable-making machine

The invention relates to a conveying device for a cable-making machine, comprising a first conveyor 5 conveying a cable wound off a spool in its longitudinal axis to a cutting station and a second associated conveyor formed of two continuous belts conveying the cable further as it is compressed vertically , wherein both straps are made softly elastic at least on opposite sides.

The invention further relates to a conveying device for a cable-making machine which takes a cable from a reel and conveys it axially to a cutting station and comprises as a feed unit at least one pair of rollers and belts intermittently used and determining the feed length of the cable, between which the cable is compressed. a pair of rollers forming a pre-arranged jetting unit arranged in front.

In an effort to rationalize the manufacture of electrical equipment, there is an increasing shift towards electrical wiring with prefabricated cable sets whose separate cables are already equipped with connection elements at their ends, such as plugs. When making separate cables, these are cut off, insulated on both sides and equipped with electrical connection elements on both sides. In this case, several cables, often of different lengths, can be connected to each other with an electrical plug. This production takes place mechanically with so-called production machines. In this case, the cable supplied in rolls is unwound, conveyed longitudinally to the cutting station and fed for fastening the coupling elements in a transverse direction relative to the respective processing stations.

2,77631

In known manufacturing machines, the transport device of the cutting station comprises a feed unit and a pre-transport unit. The feed unit is then formed by either one or more pairs of rollers 5 arranged in succession and synchronized, the two rollers of which compress the cable between them in each case and convey it further by means of the frictional forces generated between it and both rollers. Furthermore, in order to reduce the slippage between the cable to be transported and the feed rollers and to reduce the displaceable masses of this feed drive device 10, in order to achieve a faster feed drive, it has already been proposed to replace the drive roller pair with a pair of belts. However, due to the relatively high inertia of the known pre-conveyor unit, strict limits are set for increasing the feed rate. This pre-transport unit is needed due to the relatively high tensile forces which are released on the one hand when winding the cable from the reel and on the other hand by means of a forward straightening station, the function of which is to straighten the cable 20 straight. The known pre-transport unit comprises an additional roller blade which clamps the cable between them. Since the compressive forces must not be of any order of magnitude, since the cable would otherwise change in shape, large accelerations will result in a large slip between the cable and the rollers of the pre-drive device. In order to keep the slip within tolerable limits, this pre-drive device, which acts as a feed unit in a similar manner intermittently, can only be driven at low accelerations. Therefore, the known feed units are slow and do not allow the synchronization times to be shortened at the cutting station.

The known pre-conveying units are controlled by bringing the cable passage into contact between the pre-conveying unit and the supply unit. In both embodiments, this contact unit constitutes a certain source of uncertainty with respect to the operation of the cable-making machine.

DE 77631 DE patent application 3 243 906 shows figures and describes a cable manufacturing machine according to the first paragraph. In this case, one of the conveyors, which is vertical to each other in both conveying directions, comprises two superimposed continuous belts, both adjacent parts of which engage the severed end of the cable and convey the cable further vertically with respect to its longitudinal axis. To feed the end of the cable between the two parts of the belt, these are lifted up from each other in the front area by adjusting the swivel rollers, the cable is then pushed in and in this connection both parts of the belt are driven together again. This structure of the second conveyor is disadvantageous because large masses have to be moved in to feed the end of the cable. The synchronization time 15 is therefore relatively long. Moreover, in such a conveyor structure, it is not possible for the ends of two or more cables to be attached to only one plug-to-east.

The object of the invention is to provide a conveying device in which the second conveyor, which conveys the cable parts vertically with respect to their longitudinal axis, is completely independent of the feeding of the cable.

It is a further object of the invention to provide a transport unit pre-transport unit which operates without special control elements, transmits high tensile force to the cable without applying high specific pressure to the cable sheath, and operates despite intermittent cable transport without intermittently used and operated components, i.e. practically 30 viewed without acceleration forces.

The first object is solved according to the invention in that the first conveyor is provided with a channel guiding the cable in its longitudinal axis, extending at least to the second conveyor, with a pusher on the opposite side of the second conveyor pushing the cable 4 77631 through the opposite opening . Admittedly, in the conveyor formed in this way, it is necessary to move the second pusher of relatively small mass, while the conveyor belts and their reversing rollers and spray plates have no effect on the feed of the wire ends.

Another object is solved according to a preferred embodiment of the invention in that the rollers forming the pre-conveying unit are arranged to radially overlap 10 in succession and / or overlap for a certain distance, the drive takes place in the opposite direction at the same and constant circumferential speed, and the cable leading to the intermittent feed unit is between and surrounds the rollers in a certain part of their circumference. As soon as the feeder-15 feeder applies a certain pull to the end of the cable between it and the pre-transport unit, the cable settles on the circumferential surfaces of both rollers, and these carry it in the direction of the feeder unit.

It is preferred that the feed rate of the feed unit be adjusted slightly less than the circumferential speed of the rollers of the pre-transport unit. In this case, it is ensured that in the cable section between the feed unit and the pre-transport unit there are also no high-purple tensile forces between the rollers of the pre-transport unit and the cable.

It is further expedient that at least one of the rollers of the pre-transport unit has a circumferential groove for guiding the cable and that the rollers have a diameter of at least about 100 mm. The rollers should not have a smaller diameter so that the previously straightened cable does not deform too much again. Otherwise, the diameter of the rollers must be adapted to the required circumferential speed when the drive is operating at a certain speed.

In a preferred embodiment of the invention, the opening opening of the guide channel along its entire length on the second conveyor side 35 is closed by lip plates which slide into each other, the pushing edges of which rise resiliently apart from the guide channel when the cable is pushed out. The advantage of these spring plates is that the opening and closing of the control channel takes place without special control elements. The soft elastic construction of the straps allows the cables to be pushed far between the two straps, thus ensuring non-slip grip and transport of the cable.

It is further preferred that the guide channel is formed as a groove passing through a certain strip which is gripped by a pusher on the side remote from the second conveyor and which is covered on its second conveyor side by two spring plates which lip contact each other at the height of the groove. The advantage of using a strip is that the spring plates can be fastened well and that the pusher is controlled at the same time.

The manufacturing machine described in DE patent application 3,243,906 has only one hih-Napari in the second conveyor. If contact connections have to be provided at both ends of the longer cable section, the cable section must be transported longitudinally of the cable after the contact connection has been attached. For this purpose, it is again necessary that the two belt parts adhering to the cable part are lifted apart and that the cable part is conveyed by another conveying device in the direction of its longitudinal axis. This is a work step that takes a lot of time and thus prolongs the pacing time. In order to eliminate this drawback, it is therefore proposed according to the invention that the second conveyor comprises two belt drive devices arranged in succession in the contact direction of the first conveyor. The two belt drive devices are at such a distance from each other that the ends of the part of the severed cable are gripped in each case in order to continue the cable. On the side of both belt drives, processing stations are arranged, for example 35 for attaching cable connections. According to another advantage of the invention, the at least second belt drive device of the second conveyor can be adjusted in position in the conveying direction of the first conveyor and vice versa. In this case, both ends of the cable parts of different lengths can be gripped to transport them 5 further.

According to another preferred structure of the invention, the pusher is divided between the two belt drives of the second conveyor and each part has a separately controllable drive device. Thus, it is possible that the other end 10 of several cable sections is provided with a common connection contact, whereby the separate cable sections may still have different lengths.

In order for the cable to be placed correctly with respect to its length between two adjacent parts of a continuous belt, it is important that the cable is not cut until 15 have been gripped by both continuous belts. However, this means that the part of the cable to be cut is turned outwards from the axis of the fed cable. In order to avoid deformation of the cable in this unfolding and to return the initial end of the cable inserted into the guide channel gripped by the pusher to the position described above, according to the second embodiment of the invention it is proposed to provide a guide sleeve around the cable between the first conveyor and the cutting device. direction of movement, 25 when the cable is inserted between the two continuous belts.

In a preferred construction of the invention, the guide sleeve is turned according to the direction of movement of the pusher. In this case, it is expedient for the pivot shaft to be placed close to the inlet of the guide sleeve 30. This makes it possible to shape the pivot shaft immediately on the guide sleeve. However, it is also possible to arrange the pivot shaft further in front of the sleeve when viewed from the cable insertion direction. In this case, however, a detailed lever device 35 must be provided.

Il 7 77631

In another preferred construction of the invention, the guide sleeve is connected to the pusher as a power circuit, and the power circuit connection between the guide sleeve and the pusher ends at the beginning of the cutting program. In this case, the guide sleeve moves to a fixed response 5 as the pusher continues to move forward. This ensures that the guide sleeve only turns until the cable touches the fixed blade in the cutting device and the moving blade can perform the cutting function without further turning of the guide tube.

10 In order to accurately coordinate the movements of the moving blade of the pusher and the cutting device, it is expedient to connect the moving blade of the cutting device firmly to the pusher. It may even be appropriate to make the pusher side of the cutting device immediately as the cutting device blade.

The force-circuit connection between the rotatable guide sleeve and the pusher is expediently effected by pulling or compressing the rotatable guide sleeve in the shear direction against the stop 20 connected to the pusher, and that this raises it at the beginning of the cutting operation. This lifting of the guide sleeve from the stop connected to the pusher takes place so that the guide sleeve rests on a fixed stop and the pusher continues to move.

In another embodiment, the guide sleeve is tightly connected to one moving part of the cutting device and this in turn is connected as a force circuit to the pusher. In this case, the pivoting part of the guide sleeve attached to the pivoting end and the pivoting part of the guide sleeve are connected by a spring to a pusher or a moving blade, and the spring presses it into a fixed stop during the cutting operation. It is preferred that the turning part of the guide sleeve is provided with a ring blade which forms a fixed blade in the cutting operation.

The drawing illustrates structural examples of the invention, in particular Fig. 1 shows a top view of the conveying device, Fig. 2 is a section along the line AA of the first belt drive of the second conveyor, Fig. 3 is a longitudinal section along the line BB of the first conveyor, of the pre-conveying unit, Fig. 5 is a schematic view of both conveyors with a cutting device and a guide tube between them when conveying the cable in the axial direction and Fig. 6 during the cutting operation.

Fig. 7 shows a section along the line B-B from the first conveyor and Fig. 8 a section along the line A-A from the second conveyor.

Figures 9 and 10 show two different embodiments of a guide tube turning device.

The cable 1 is wound out of a drum, not shown, and conveyed by a first conveyor 2 in the direction X. This first conveyor comprises a pair of belts 3,4, the parts 5,6 of which press the cable 1 between them. The rollers 7.8 drive a belt drive. The rollers 9,10 form pivot rollers, while the rollers 11,12 only increase the compression pressure of the belt parts 5.6 on the cable to be further conveyed. From the conveyor 2, the cable 1 is inserted into a channel 14, the strip 25 of which is formed by a longitudinal groove and spring plates 16 and 17. From the opposite side of the second conveyor, the pusher 18 formed of a thicker plate strip goes into the longitudinal groove of the strip 15. This pusher 18 pushes the edge regions 17 of the spring plates 16, 17 of the cable 1 as a transiently resiliently rise 30 between the interconnected parts 20, 21 of the belts 22 and 23 forming the second conveyor 24. The belts 22 and 23 are made of an elastic material or have at least a soft elastic upper surface so that the cables 1 can be pushed so far between the overlapping belt parts 20, 21 that the conveyor 24 securely engages the cable parts 1. Before

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9 77631 as the pusher 18 presses the cable 1 onto the second conveyor 24, it is cut to the correct length by the cutting device 13.

The strip 15 of the cable supply system is bevelled towards the second conveyor 24. Each oblique surface 5 has a spring plate 16,17 attached to an end 25 remote from the second conveyor. The two spring plates 16,17 are lip-spaced at each end 19. These free, prestressed ends of the spring plates 16,17 open from the pressure of the pusher 18 and allow the cable 1 to come out of the channel 14. The sharp angular arrangement of both spring plates 16,17 allows the cable ends to be guided as far apart as possible between the two belt parts 20 and 21.

The second conveyor comprises belt drive devices 24 and 26 arranged in succession in the conveying direction of the conveyor 2. The belt drive 26 is formed in exactly the same way as the belt drive 24. However, the belt drive 26 can be adjusted in the Y and Z directions together with the processing station 20 to secure the contact pieces. Due to the arrangement of the second belt drive device 26, the cable parts 1 cut to the correct length by the cutting station 13 can be handled at both ends by means of abutment stations 27 and 28.

The feed system for the second conveyor consisting of both belt drive devices 24 and 26 comprises two split pushers 18 and 29, the operation of which can be controlled separately. In this way, it is also possible to handle both ends of the very long cable sections 1 at the same time. In this case, the cable 1 30 is pushed through the conveyor 2 so far that its free end is at the height of the processing station 27. With the pusher 29, the end of the cable is pushed between the two adjacent parts of the belt drive 26 and further conveyed to the handling station 27. The conveyor 2 is then driven once more. In this case, a cable passage is formed between the two belt drive devices 10 77631 24 and 26. The cable 1 is then cut at the cutting station 13 and the other end of the cut cable is pressed by a pusher 18 between the belt parts 20, 21 of the belt drive device 24. This end of the cable is conveyed to the processing station 28 by means of the belt drive devices. By means of a split pusher, it is possible to provide several cable sections at one end with the same connection contact. To this end, the conveyor 2 pushes the cable 1 so that its free end reaches the height of the processing station 27. Station 13 cuts the cable 1, and pushers 18 and 29 push it between the belt drive devices 24 and 26. The belt drive 24 is started and the severed end of the cable is transported to the stop station 28. In this connection, the first conveyor 2 pushes the cable 1 for this free end 15 again to the height of the processing station 27, and the pusher 29 pushes it between the belt drive device 26. Here, the ends of both cable sections are next to each other and can be equipped together with a plug connection. If both parts of the cable have to be of the same length, a pusher 18 is also used at the same time. The part of the cable cut by the station 13 is now pushed between the belt drive 24 by means of a pusher 18, which transports it to the processing station 28.

Figure 4 illustrates a structural example of a pre-conveying device. A roller, not shown, pulls the cable 1a in the direction X and passes through a straightening station 2a consisting of several rollers. Since the pulling of the kaa-30 game 1a by the roller and its guidance through the straightening station 2a involve high traction forces, a special pre-conveying unit is provided for this purpose, comprising rollers 3a and 4a. The shafts 5a and 6a of the rollers 3a and 4a are pushed in the radial direction of the rollers so that they are both side by side and also 35 on top of each other. The rollers 3a and 4a are arranged on the shafts ti u 77631 5a and 6a so that they overlap. However, it is also possible to arrange the rollers straight down. In this case, however, the angle of rotation is reduced to 180 °, and the tensile force transmitted by the rollers to the cable is then slightly reduced.

From the pre-transport unit 3a, 4a, the cable 1a is further transferred to a feed unit comprising, in the example shown, both rollers 7a and 8a. This feeding unit 7a, 8a takes care first of all of moving the cable 1a forward, but at the same time also of maintaining the exact feed length 10 of the cable. A cutting station consisting of blades 9a, 10a is arranged behind the feed unit 7a, 8a.

When the cable 1a is further conveyed through the supply unit 7a, 8a, a certain traction force is applied to the part of the cable 1a between the supply unit and the pre-transport unit 4a, 5a. In this case, the cable 1a contacts the circumferential surface of the rollers 4a, 3a, whereby a friction barrier is created between the cable 1a and the rollers 3a, 4a. As a result of this friction barrier, the cable 1a moves out of the cable reel and through the straightening station 2a. As the cable 1a wraps around the rollers, a very large friction barrier is created, which is a multiple of the attraction of the feed unit 7a, 8a or the pre-conveyor formed, respectively.

The cable Ib is unloaded from the drum shown in Fig. 1, and is conveyed by the first conveyor 2b in the direction X. This first conveyor comprises a pair of belts 3b, 4b, parts 5b, 6b of which compress the cable Ib between them. The rollers 7b, 8b drive a belt drive. The rollers 9b, 10b form the turning rollers, while the rollers 11b, 12b increase the compression pressure of the belt parts 5b, 6b on the forward 30 cable. The first conveyor 2b pushes the cable Ib into the channel 14b formed by the longitudinal groove of the strip 15b and the spring plates 16b, 17b. From the side further away from the second conveyor, the pusher 18b formed of the stronger plate strip goes into the longitudinal groove of the strip 15b. This pusher 18b pushes the cable Ib of the spring plates 16b, 17b 12 77631 under a transient elastic elevation of the edge regions 19b between the interconnected parts 20b, 21b of the belts 22b, 23b forming the second conveyor 13b.

The belts 22b, 23b are made of elastic material or at least have a soft elastic upper surface, so that the cable Ib can be pushed so far between the overlapping belt parts 20b, 21b that the conveyor 13b securely grips the cable Ib. When the pusher 18b is compressed on the second conveyor 24b of the cable Ib, the cutting device 24b, 25b cuts 10 to its desired length.

As can be seen from Fig. 5, a guide tube 28b is arranged between the first conveyor 2b and the cutting device 24b, 25b, through which the cable Ib passes. This guide tube 28b is pivotally mounted on the shaft 27b and is pivoted by the pusher 18b to the inlet of the belt parts 20b, 21b, as shown in Fig. 6, so that the cable Ib contacts the fixed blade 24b of the cutting device. As the pusher 18b moves back, the guide tube 28b also returns to its original position in the manner shown in Fig. 5. The purpose of the guide tube is to prevent the cable part 1a from changing shape with the cable shaft Z and that the cable returns to the shaft Z after cutting, so that the free end of this part Ib can be securely threaded into the channel 14b.

In the construction of the turning device shown in Fig. 10, the tension spring 19b presses the pivotable guide sleeve 28b on the shaft 27b against a movable stop 30b rigidly connected to the movable blade 25b and the pusher 18b. When the pusher 18b is driven to the inlet of both parts 20b, 21b of the continuous belts 22b, 23b, the movable stop 30b is adjusted in the direction V. During the adjustment operation of the stop 13b, the tension spring 29b also ensures 28b contacts the fixed response 31b. In this position of the guide-35 sleeve, the cable Ib contacts the fixed blade 24b of the cutting blade. As the movable blade 15 moves further forward, the cable Ib is broken. During this cut-off operation, the movable stop 30b rises from the guide sleeve 28b. During the cutting operation, when the cable Ib is on the fixed blade 24b, the guide sleeve 28b does not turn. As the pusher 18b moves back, the guide sleeve 28b moves back to its marked initial position against the force of the tension spring 29b.

In the turning sleeve 28b of the guide sleeve 28b shown in Fig. 9, the front pivoting end 31b of the guide sleeve 28b enters the recess 32b of the loop-shaped portion 26b connected to the pusher 18b. The coupling of this part 26b to the pusher 18b takes place as a force circuit, whereby the compression spring 22b presses the flange 34b rigidly connected to the pusher 18b against the edge 35b of the recess 36b. When the pusher 18b is driven to the entry point of the conveyor 15 13b, the loop-shaped part 26b moves through the spring 33b in the direction V so far that it contacts the fixed stop 37b. This flange-shaped portion 26b is formed at 38b as a ring steel. In this ring blade, the movable blade 25b cuts the cable Ib.

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Claims (22)

A conveyor device for a cable making machine and consisting of a first conveyor (2) which transports it from a reel wound cable (1) in the direction of its longitudinal axis to a cutting station and a second connected conveyor (24) formed by two endless belts (20, 21), which interconnecting the cable (1) between them perpendicular to the cable shaft, further convey the same, the two belts (20, 21) at least on the opposite sides (22, 23). soft elastic, characterized in that, to the first conveyor (2), a cable (1) joins the longitudinal axis (14) of the longitudinal shaft direction and at least to the second channel (14) of the second conveyor 15, in which output from the the opposite side of the second conveyor (24) connects a slide (18), which pushes the cable (1) through an opposite lying and openable slit between the belts (20, 21) of the second conveyor (24) at the advance of the slide (18). . 20 2. A transport device according to claim 1, characterized in that the slot openable over the entire length of the second conveyor (24) in the guide channel (14) is sealed by lip-abutting spring plates (16), the bump edges (19) at which the projection of the cable (1) out of the control channel (14) resiliently rises from each other. Transport device according to claim 1 or 2, characterized in that the control channel (14) is formed by a continuous groove in a strip (15), in which on the side facing away from the second conveyor (24) a slide (18) and the side facing the other conveyor (24) is covered by two spring plaques (16), which above the groove bump lip-to-mouth. 4. A conveying device according to claim 1, characterized in that the second conveyor consists of two pulleys (24,26) in the conveying direction of the first conveyor (2). Transport device according to claim 4, characterized in that at least one belt drive (26) 1 of the second conveyor can be adjusted with respect to the 5 position in the transport direction of the first conveyor (2) in the opposite direction. 6. A conveyor device according to claim 5, characterized in that the second belt drive (26) seen in the first conveyor (2) in the second conveyor can be set with respect to the position of the first conveyor (2). 7. A conveying device according to claim 4, characterized in that the port between the two belt drives (24,26) of the second conveyor is divided into two parts (18,29) and that each part experiences a separate controllable drive. 8. A conveying device according to claims 1-7 for cable making machines, consisting of a first conveyor (2b) arranged before the cutting device (24b, 25b, 26b), which transports it from a roll of unwound cable 20 (1b) in the direction of its longitudinal shaft, and a second conveyor arranged behind the cutting device, which is formed by two endless belts (22b, 23b) which further transport the cable between them perpendicular to the cable shaft and a slide (18b) which projects the cable perpendicular to its longitudinal shaft in the inlet of the two endless belts (22b, 23b), characterized in that between the first conveyor (2b) and the cutting device (24b, 25b, 26b) there is arranged a cable (1b) surrounding guide sleeve (28b) which, when inserting the the cable (1b) between the two endless belts (22b, 23b) follows the direction of movement of the slide (18b). 9. A transport device according to claim 8, characterized in that the guide sleeve (28b) 1 is pivoted in correspondence with the direction of movement of the slide (18b) about an axis (27b). 10. A transport device according to claim 9, characterized in that the pivot shaft (27b) is located near the entrance opening of the guide sleeve (28b). Transport device according to any of the preceding claims, characterized in that the guide sleeve (28b) is connected 1 SEK for retaining connection with the slide 5 (18b). 12. A transport device according to any one of the preceding claims, characterized in that the movable knob (25b) in the cutting device is fixedly connected to the slide (18b). A conveying device according to claim 12, characterized in that the saddle (18b) facing the cutting device (24b, 25b) is formed as knlv (25b) for the cutting device. 14. The conveying device according to any one of the preceding claims, characterized in that the power coupling between the guide sleeve (28b) and the slide (18b) is canceled when the housing starts and that the guide sleeve (18b) will then lean against a stop (31b). Transport device according to any one of the preceding claims, characterized in that the pivotable guide sleeve (28b) is pulled or pressed by means of a spring force 1 against a stop (30b) connected to the slide (18b) and lifted off from the stop in that cap. begins. Transport device according to claim 15, characterized in that the lifting of the guide sleeve (28b) from the stop (30b) connected to the slide (18b) takes place by the guide sleeve (28b) coming into contact with a fixed stop (31b) and the slide ( 18b) goes further. 17. A conveying device according to any of the preceding claims, characterized in that the guide sleeve (28b) is formally connected to a part (26b) of the cutting device and that it is in turn connected to the slide (18b). 18. A transport device according to any one of the preceding claims, characterized in that