EP0371391A1 - Process for automatically transporting textile materials deposited in recipients - Google Patents

Abstract

The invention relates to a process for the conveying of textile material deposited in recipients from a machine discharging textile material to a machine receiving textile material, by means of a self- propelled transport vehicle (F), the travelling control of which takes place from a central control unit (Z). What is disadvantageous with the known systems is that, in spite of a self-propelled transport vehicle which automatically transfers the recipients from one machine to the other, with these systems no fully automatic operation without manual intervention is possible. That means that with these systems the manual intervention in some cases has to take place within short periods of time. According to the invention, it is therefore proposed that the controlling of the transport vehicle for returning the recipients (11) to be taken away from the machine (S1, S2) receiving the textile material to the machine (K1 to K3) discharging the textile material is undertaken by the central control unit on the basis of control signals emitted to the control unit (Z) and that there is provided on the route of the transport vehicle (F) from the machine (S1, S2) receiving textile material to the machine (K1 to K3) discharging textile material a test station (L) for checking the content and/or the state of the recipients located on the transport vehicle and the test station is in connection with the control unit. <IMAGE>

Description

The invention relates to a method for the automatic transport of textile material stored in containers according to the preamble of patent claim 1.

To increase productivity and quality, the automatic transport of textile material between the individual spinning machines is becoming increasingly important.

For example, DE-OS 3532172 shows a device, the control of a transport vehicle, the card control device and the route control device being connected to a central control unit. This system is also a buffer control for the recording of full and empty cans, the buffer control also being connected to the central control unit.

This makes it possible for the machine taking up a sliver which is arranged downstream of a sliver to be automatically supplied with cans filled with sliver. The jug is transported to the subsequent machine by means of a transport vehicle which is guided over a fixed guide track.

If the known system breaks the belt, for example on the line, or if the can malfunctions due to damage, manual intervention is required. The same applies to the necessary replacement of the vehicle battery and the disposal of sliver residues remaining in the cans.

It is therefore not possible to run this system automatically for several hours without manual intervention. Rather, it is a semi-automatic system, with individual processes being carried out by hand.

The object of the invention is to propose a method or a device in which the transport of containers which convey textile material is designed to be fully automatic, the necessary manual interventions are limited to a minimum, the same being necessary only after relatively long intervals and the exchange of the containers can be done in short periods of time.

This object is achieved by the method according to the characterizing part of patent claim 1.

Advantageous further developments of the method can be found in the following subclaims.

The proposed method in a control station makes it possible for the corresponding can with the remaining amount to be fed to the control station if a belt breakage of a subsequent textile material-absorbing machine, for example a stretch, occurs after a reserve belt has been automatically fed from a reserve can assigned to the can .

Depending on the degree of filling determined, either the can in the control station is emptied or the beginning of the belt is searched for by a device and given back to the route to a clamping and transfer device located on the vehicle or on the container.

After a predefined time interval or a predefined clock frequency, the battery located on the vehicle is automatically replaced by a battery located at the reserve station. The battery removed from the vehicle is fed to a charging station for recharging and, after checking the state of charge, can in turn be exchanged for the replacement battery which is now on the vehicle after a further time interval.

By combining several automatic functions in one control station, it is possible to concentrate all the devices that are necessary for this to summarize the This in turn requires easier maintenance and easier checking of the individual units.

By attaching smaller stores for defective cans that have been removed and intact cans to be replenished, and a store for the textile material removed from the containers, it is possible to distribute a necessary manual intervention over large intervals. Visual monitoring is only occasionally necessary during fully automatic operation.

When using different materials, for example cotton and polyester, it is proposed to feed the textile material removed in the control station to an intermediate store corresponding to the material. This process is controlled by the computer on the control station, whereby it has recorded and temporarily stored the can parking space which the can to be emptied previously occupied on the route.

To simplify the system, it is proposed that the transport commands be transmitted to the transport vehicle only when it is in the waiting position in the control station.

The transport vehicle itself is only provided with a simple computer system, which is used to convert the driving signals received from the control station. Other functions such as loading and unloading cans and steering the transport vehicle are also linked to this computer.

Because damage to the container is relatively rare occurs, it is advantageous not to carry out the functional test of the containers continuously, but rather at predetermined time intervals.

The proposed implementation of all automatic functions in the control station while the transport vehicle is in a fixed position makes it possible to design the entire control station in a compact form, that is to say with minimal external dimensions.

To increase the capacity, it is also proposed to equip the control station with an additional memory for full and empty cans.

By connecting the central control unit to a central computer for the process control system, it is possible to adapt the commands issued by the control unit to the transport vehicle even better for the entire machine process. The control of the central control unit is subordinate to the control commands of the central computer.

The proposed device, wherein the transport vehicle is guided on a common guideline between the delivery and pick-up points arranged in series and outside of it on a loop-shaped path, with the control station being arranged in one, enables a compact arrangement or an optimal use of space, short Routes and the connection of another transport cycle.

Further advantages are described and shown in more detail using the following exemplary embodiments.

• Figur 1 schematisch eine Draufsicht auf eine Spinne­reivorwerksseinrichtung mit 3 Karden und 2 Strecken und einer fahrbaren Kannentrans­porteinrichtung.
• Figur 2 ein Flussdiagramm der automatischen Steue­rungseinrichtung einer Leitstation.
• Figur 3 eine weitere Ausführungsform nach Fig. 1.

Show it:

• Figure 1 schematically shows a plan view of a spinning mill with 3 cards and 2 lines and a mobile can transport device.
• Figure 2 is a flow diagram of the automatic control device of a control station.
• FIG. 3 shows a further embodiment according to FIG. 1.

In Figure 1, 3 cards K1 to K3 are arranged in series. The sliver produced in the cards is placed in the cans B1 to B3 via a funnel wheel. In addition to the jug that holds the tape, there are additional spaces on the cards for empty and full jugs. These parking spaces represent a kind of buffer. In the example shown, a storage space for a full and a storage space for an empty can is provided. However, further pitches can be arranged.

The cards K1 to K3 are followed by 2 draw frames S1, S2 which further process the textile material emitted by the cards. The cards K2 to K3 are connected to the lines S1 S2 via a transport device. The transport device is formed from a transport vehicle F guided over a guide track 1. The transport vehicle F is provided with a travel drive (not shown in more detail) and a steering device which is controlled by sensors which scan the guide track 1.

The transport vehicle F also has a can slot 3 and a calculator 2. The computer 2 is used in part to receive and process the driving commands received from a control station L and is also responsible for the control for loading and unloading the cans and for the steering mechanism. It is also possible to provide the transport vehicle with additional pitches.

The control station L already mentioned is located in relation to the route of the transport vehicle F between the lines S1, S2 and the cards K1 to K3.

In the example shown, the transport vehicle only moves in one direction of travel and, after it has passed the delivery points 4 of the cards K1 to K3, along the can frames 5, 6 of the lines S1, S2 before it reaches the control station L. The transport circuit is closed after the transport vehicle F has passed the control station L and has returned to the delivery points 4 of the cards K1 to K3.

The control station L has a central control unit Z, which is connected in terms of control technology via connecting cables 9, 10 to the cards K1 to K3 and the lines S1, S2. For inclusion in the overall process control, the control unit Z can be connected to a superordinate central computer 37.

Via connection 9, it is communicated how the can positions of delivery point 4 of cards K1 to K3 are occupied, and via connection 10, central control unit Z receives a message from routes S1, S2 if one is in can rack 5, 6 sensitive jug is empty or there is no more tape due to a broken belt. Both processes, belt break or empty can, trigger the same signal.

In the example shown in FIG. 1, it was reported via link 10 from route S2 that the can 7 located in the can frame 6 has run empty. The reserve band of the reserve jug 7a was automatically applied via a tracking device, not shown in detail.

The central control unit Z transmitted the control command for starting the can frame 6 to the transport vehicle F originally in a waiting position in the control station in order to pick up the empty can 7 there.

In order to approach the can parking spaces precisely, they can be provided with individual sensors or markings which interact with the drive of the transport vehicle via sensors attached to the transport vehicle.

After the can 7 has been picked up via a can handling device (not shown in any more detail), the transport vehicle F drives with the empty can 7 into the control station L.

In the control station (FIG. 2), the can 7 located on the transport vehicle F is checked by means of a level meter 11 whether there is still textile material in the can. If the state 12 is "empty", the can is checked for its function by a function checker 13. These Functional testing can also only be carried out at predetermined intervals. If there is a positive result 14, the can 7 with the transport vehicle F is released by the control station L and automatically travels to the delivery point 4 of the card K3 and places the empty can 7 there.

On the basis of the signal transmitted to the transport vehicle F in the control station L that the full can 8 of the card K1 is ready for collection, the transport vehicle F drives to this delivery point 4 of the card K1 and takes over the full can 8. The can 8 is then returned to the original one The location of the can 7 in the can rack 6 of route S2 is transferred. After delivery of the can 8, the transport vehicle F returns to its waiting position in the control station.

Another possibility is to provide an empty can parking space 38, indicated by dashed lines, for the can frames 5 and 6. This makes it possible to prevent the vehicle F from running empty, that is to say that on the way from the control station L to the route S2, the transport vehicle can take over a full can 8 from the card K1 and place it on the empty identification parking space 38 of the route D2. If the vehicle F has a limited possibility of reversing, the empty can 7 can then be picked up when the full can 8 is parked and transferred to the control station L.

If, in the previously described process in the control station L, the fill level meter 11 determines a residual fill level which is smaller than a predetermined minimum fill level value 15, the can is emptied via a device 16 and the drained Material is supplied to a memory Sp1 or Sp2, the empty can then being subjected to the functional test 13 as previously described. If this function test 13 yields a negative value 17, an exchange device 18 exchanges this can and feeds it to a repair store 19. At the same time, a replacement can is supplied to the can parking space 3 of the transport vehicle F from an empty can memory 20 via the exchange device. In the example shown, this supplied can also passes through the function check 13.

If it is determined on the fill level measurement 11 that the fill level value 21 is greater than a minimum preset value, a band search device 22 is activated. This device 22 searches for the beginning of the belt of the remaining quantity in the can and transfers the beginning of the belt to message 23 "beginning available" to a holding and transfer device (not shown) of the transport vehicle or the can. The transport vehicle then receives the release and transfers the partially filled jug with the recorded belt start to the missing location on route S1 or S2.

If there is a negative message 24 "not found" in the band search device 22, this can is emptied via the emptying device 16 in accordance with the previously described process.

While the vehicle is in the control station, the temporarily stored signals "get can" 25 or "bring can" 26 are transmitted to computer 2 of vehicle F and thus the route for the can parking spaces to be approached is specified.

A time element 27 activates an exchange device 28, which takes out the battery located on the vehicle F and feeds it to a charging station 29. The charged battery is then fed to a test device 31. If this test yields a positive value 32, the recharged battery is transferred to a reserve station 30. At the same time, a reserve battery is fed to the transport vehicle F from the reserve station 30 by means of a charging device 33. The exchange device 28 and charging device 33 can consist of one device.

If the functional test of the battery yields the value "defective" 34, it is discharged to a repair memory 43 and a new battery from a spare reserve 42 is added, manually or automatically. If it turns out during the check of the battery delivered to the repair memory 43 that the battery can still be used, it is, as indicated, returned to the alternating circuit via the charging device 29 after repair.

For the time element 27, by means of which the temporal exchange periods are specified, an additional charge control 35 is attached to the vehicle F, which can also trigger the described exchange process of the battery in the control station L in the meantime when a falling state of charge is determined. The battery replacement periods can be adjusted according to the duration of use.

The battery change process coincides with the others ren automatic functions coordinated via the central control unit Z. For reasons of clarity, the connection lines of the individual functions to the central control Z have been omitted in the illustration according to FIG. It goes without saying that all functions are linked and managed by the central control unit Z.

A further embodiment is shown in FIG. 3, the travel paths between the route and the card partially overlapping and 4 cards K1-K4 delivering textile material to a line S1 receiving textile material are provided.

The route S1 is followed by a route S2 via a further guideline 1a, the guideline 1a ending in a guideline loop 39 of the guideline 1. The guide station L is located in this guide loop 39.

Between the cards K1 - K4 and the can frame 5 of the route S1, the guideline overlaps, while on the side opposite the guideline loop 39 another guideline loop 40 is used for the reversal or return of the transport vehicle F to the control station.

The further guideline 1a is provided with a reversing loop 41.

With this proposed arrangement, the changing operations of the cans in connection with the control station are reduced to a minimum in time.

The parallel arrangement of the delivery points 4 of the cards K1-K4 and the take-up points 36 makes it possible to transfer the full cans quickly and directly to the take-up points of the can rack 5.

The further connection of a subsequent route S2 results in additional utilization of the installed control station.

The use of a second transport vehicle is advantageous here

The procedure in the control station L, as well as the can change, corresponds to the execution according to FIG. 1 except for the guiding of the guidelines.

The invention is not limited to these exemplary embodiments, since deviations in the sequence of functions are possible.

Reference numerals

• 1.1a lead track
• 2 computers
• 3 parking spaces
• 4 delivery point
• 5 can rack
• 6 can rack
• 7.7a jug
• 8 jug
• 9 connection cables
• 10 connecting cables
• 11 level meter
• 12 empty
• 13 functional testers
• 14 positive
• 15 <min
• 16 emptying
• 17 negative
• 18 exchange
• 19 repair memory
• 20 empty can memory
• 21> min
• 22 band search device
• 23 beginning available
• 24 Beginning not found
• 25 signal "fetch can"
• 26 signal "bring pot"
• 27 time element
• 28 Battery replacement
• 29 shop
• 30 battery reserve
• 31 test station
• 32 positive
• 33 Charge
• 34 defective
• 35 Charge control
• 36 reception point
• 37 central computer
• 38 pitches
• 39 Guideline loop
• 40 guideline loop
• 41 reverse loop
• 42 spare reserve
• K1-K4 card
• S1-S2 route
• L control station
• F transport vehicle
• B pitchers
• Z Central control unit
• SP1 memory
• Sp2 memory

Claims (17)

1. Method for conveying textile material stored in containers (7, 8) of a textile material-dispensing machine into a textile material-receiving machine by means of a self-propelled transport vehicle F guided by a guideline (1), the driving control of which is carried out by a central control unit (Z) which is connected to the Textile material-dispensing (K1-K3) and the textile material-receiving machines (S1, S2) and for returning the containers emptied on the textile material-receiving machine to the textile material-dispensing machine, characterized in that
that a control station (L) is provided in the route of the transport vehicle, which passes through the transport vehicle (F) on its way from the textile material-receiving (S1, S2) to the textile-material-dispensing machine (K1-K3), at or in the Control station (L) the following functions are carried out automatically:
- Transmission of the control commands for the route of the transport vehicle by the central control unit (Z) integrated in the control station.
- Check the container contents (11).
- Check the condition of the container (13).
- Exchange, recharge and verification (28, 27) of an energy source attached to a transport vehicle, for example a battery. 2. The method according to claim 1, characterized in that
that the battery in the control station (L) is automatically exchanged for a battery that is kept in reserve when a low state of charge of the battery is determined, or when a predetermined time or pulse specification is reached. 3. The method according to claim 1, characterized in
that filled and empty containers are temporarily stored at the control station (L). 4. The method according to claim 1, characterized in
that in the event of a partial emptying of a container which does not exceed a predetermined degree of emptying (21), the container of the machine (S1, S2) absorbing textile material is returned via the transport vehicle (F). 5. The method according to claim 4, characterized in
that the textile material consists of a sliver and the beginning of the sliver of the determined residual quantity is automatically detected (22) and delivered to a holding device of the transport vehicle or the container. 6. The method according to claim 1, characterized in
that the textile material consists of a sliver and that if a partial emptying of the container is found that does not exceed a predetermined degree of emptying, the beginning of the sliver is searched one or more times via a sliver search device and if the beginning of the sliver is not detected after a predetermined number of search intervals, the remaining amount of the container is removed and is sent to a recycling process. 7. The method according to claim 1, characterized in
that if a partial emptying of a container is detected, which exceeds a predetermined degree of emptying (15), the remaining amount of textile material in the container is removed and sent to a recycling process. 8. The method according to claim 7, characterized in that
that the supply of the remaining quantity removed from the container is controlled according to the previous location of the container on the machine receiving the textile material to an intermediate store (SP1, Sp2) provided for the material via the central control unit (Z). 9. The method according to claim 1, characterized draws,
that the control commands to a control unit (2) arranged on the transport vehicle (F) can only be transmitted by the central control unit (Z) while the transport vehicle is in the control station (L), the signals emitted and received by the textile material, while the transport vehicle is outside the control station, are temporarily stored in a queue on the computer of the central control unit (Z). 10. The method according to claim 9, characterized in
that the transport vehicle (F) is in its waiting position in the control station. 11. The method according to claim 1, characterized in
that the container remains on the transport vehicle (F) during the execution of the automatic functions in the control station (L). 12. The method according to claim 1, characterized in that
that the container for at least one of the automatic functions carried out in the control station (L) is removed from the transport vehicle (F) and transferred to a station of the control station. 13. The method according to any one of claims 11 or 12, characterized in that
that the transport vehicle (F) is in a fixed waiting position during all automatic functions in the control station. 14. The method according to claim 1, characterized in that
that the central control unit (Z) is connected to a central computer (R) for the process control system. 15. The method according to claim 1, characterized in
that the status of the container is checked in a predetermined time interval. 16. The apparatus according to claim 1, characterized in
that the container delivery points (4) of a plurality of machines delivering textile material and the container reception points (34) of at least one machine (S1, S2) receiving textile material are each arranged in a row, the row of delivery points (4) and that of the reception points (36) being parallel face each other and the transport vehicle moves between these rows on a guideline attached parallel to these rows, the transport vehicle being guided outside and at both ends of these rows via a closed guideline loop and the control station (L) being arranged in one of these loops. 17. The apparatus according to claim 16, characterized in
that another guideline opens into the guideline loop in which the guiding station is arranged, which enables a transport connection of further textile material-dispensing and receiving machines.

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