JP6890500B2 - A method of operating a composite system consisting of at least one ring spinning machine and at least one winder, and a winder for the composite system. - Google Patents

Description

The present invention relates to a method of operating a composite system consisting of at least one ring spinning machine and at least one winder, and a winder for the corresponding composite system.

In a ring spinning machine, cups are manufactured with a relatively small yarn volume. These cups are unwound in a winder into a large volume twill roll package. Ring spinning machines and winders can be operated in a complex system. That is, the ring spinning machine and the winder are connected to each other via an automatic transfer system. This transport system transports cups from a ring spinning machine to a winder and an empty cup winding tube from a winder to a ring spinning machine. In order to avoid downtime, the processing volumes of the winder and ring spinning machine operating in a complex are harmonious with each other. At this time, such harmonization is usually performed so that a ring spinning machine with a much larger number of working units, which is significantly slower in the working process, does not have to wait for the winder. Generally, the processing amount of the winder is selected to be slightly larger than the processing amount of the connected ring spinning machine. As a result, the normal rollback machine has already rewound the supplied cup before the ring spinning machine newly duffs it and thus the new cup is provided. At this time, "duffing" means removing each of the manufactured cups together from the working unit of the ring spinning machine. Here, it is also called "deep frying".

In the case of the complex system described in European Patent No. 1006069 (EP 1 006 069 B1), the cup supply to the winder is continuously monitored by the sensor. The control device of the winding tube monitor, on the one hand, stores the transport plate with the empty winding tube in the transport system of the winder when there is no supply of cups, and on the other hand, winds through the central control unit. It starts to control the taker to reduce the drive to the specified energy saving operation state. Furthermore, when the supply of the cup is restarted, it is guaranteed that the winder is controlled to increase the drive from the energy saving operation state to the normal operation state.

An object of the present invention is to optimize the operation of a winder forming a complex with a ring spinning machine.

This problem is solved by operating a complex system consisting of at least one ring spinning machine and at least one winder. The cup is manufactured in a ring spinning machine, processed in the working unit of the winder and rewound into a twill winding package. The take-up machine winds up at a predetermined take-up speed in the operating state "wind-up". The work unit of the winder is stopped in the operating state "stop" to shut off unnecessary consumer machines of the winder. The winder is operated in the operating state "winding" to process each cup of frying in at least one ring spinning machine in the winder. When each cup of the frying of at least one ring spinning machine has been processed in the winder and the next cup of frying of at least one ring spinning machine is not yet provided, the winder is in operation. Operate with "stop". A selection is made between at least one first mode of operation and a second mode of operation. In order to achieve less energy consumption in the second operation mode than in the first operation mode, in the second operation mode, the take-up speed and the duration in the operation state "stop" are set to the first operation, respectively. Higher and longer than in mode. In order to achieve higher quality of the manufactured twill winding package in the first operation mode than in the second operation mode, in the first operation mode, the take-up speed and the duration in the operation state "stop" are set. , Lower and shorter than in the second operation mode, respectively.

According to the present invention, the energy consumption of the winder is the lowest when the winding is performed at the maximum feasible winding speed, and thus a correspondingly long duration occurs in the operating state "stop". Based on recognition. Indeed, relatively high take-up speeds result in relatively high speeds, which in turn results in relatively high power consumption of the take-up drive, but on average the energy consumption of the take-up drive is take-up. It changes almost independently of speed. It is the consumer that is important for energy saving in the second operating mode, the power consumption of this consumer does not depend on the take-up speed, and this consumer can be shut off in the operating state "stop". it can. Therefore, each time the duration in the operating state "stop" is extended, energy savings are brought about. The greater the power consumption of these consumers, the greater the energy savings due to the extended duration in the operating state "stop". In particular, one of such consumer machines is the negative pressure supply unit of the winder. Furthermore, it should be noted that in fact all unnecessary consumer units are shut off in the operating state "stop". This includes not only consumers that are directly required for winding, but also indirect consumers. That is, the consumer of the winder is usually supplied with power from the DC voltage intermediate circuit. When all the consumers connected to the DC voltage intermediate circuit are cut off, the DC voltage intermediate circuit is also cut off, and thus the power loss of the DC voltage intermediate circuit can be reduced.

Relatively high take-up speeds and relatively long downtime do have the benefit of energy savings, but they also have unfavorable aspects. Relatively high take-up speeds and relatively long downtime adversely affect the quality of manufactured twill roll packages. At relatively high take-up speeds, the friction acting on the yarn increases. As a result, the fluffing of the yarn increases. When the quality of the yarn deteriorates, the quality of the twill winding package deteriorates. In the "stopped" operating state, flying debris accumulates unimpeded on the stopped twill-wound package. As a result, the quality of the twill-wrapped package is further deteriorated.

Therefore, an important aspect of the method according to the invention is the selection of a first operating mode and a second operating mode. In the first mode of operation, the relatively high quality of the twill winding package is achieved, and in the second mode of operation, the energy consumption of the winder is reduced.

According to a preferred embodiment of the method according to the invention, the take-up speed is set to be greater than the boundary take-up speed, at which the fried cup is processed only when the next fried cup is provided. It will be done.

The method according to the invention does not affect the productivity of the method according to the invention, as long as it does not fall below the boundary winding speed. In this case, the cycle time consisting of the operating state "winding" and the operating state "stop" is the same for the first operating mode and the second operating mode. If the take-up speed is below the boundary take-up speed, the quality can certainly be further improved in some situations, but this reduces productivity. In this case, it is possible that the winder has not yet finished winding the next frying cup, even if the next frying cup is provided. That is, in this case, it can be said that the ring spinning machine has to wait for the winder.

Further, this problem is solved by a complex system with a control device consisting of at least one ring spinning machine and at least one winder. The ring spinning machine is configured to manufacture cups, and the working unit of the winder is configured to process the cups and rewind the cups into a twill winding package. The winder can be operated at a predetermined winding speed in the operating state "winding". The work unit of the winder is stopped in the operating state "stop", and unnecessary consumers of the winder are shut off in the operating state "stop". The control device is configured to operate the winder in the operating state "winding" and at least one ring in order to process the spinning cup of at least one ring spinning machine in the winder. When the spinning spinning cup has been processed in the winder and the next ring spinning cup of at least one ring spinning machine is not yet available, the winder should be operated in the operating state "stopped". It is configured in. An operating device is provided, from which at least one first operating mode and a second operating mode can be selected. In order to achieve less energy consumption in the second operation mode than in the first operation mode, in the second operation mode, the take-up speed and the duration in the operation state "stop" are each set to the first operation. Higher and longer than in mode. In order to achieve higher quality of the manufactured twill winding package in the first operation mode than in the second operation mode, the take-up speed and the duration in the operation state "stop" in the first operation mode are used. , Lower and shorter, respectively, than in the second operating mode. The control device is configured to operate the winder in the operation mode selected by the operating device.

The present invention relates to a winder for the above-mentioned composite system, wherein the control device and the operation device described above belong to the winder.

Thus, the composite system according to the invention or the winder according to the invention has an operating device that allows the operator to choose between improving quality and reducing energy consumption.

According to a further configuration of the present invention, the operating device comprises means for increasing or decreasing the take-up speed in a stepwise manner to reduce energy consumption or improve the quality of the manufactured twill roll package.

Such a configuration of the operating device allows easy adjustment of three or more modes of operation. Thereby, in an advantageous way, it allows various weights of quality and energy consumption. For example, such a configuration may be configured as a slide adjuster.

Hereinafter, the present invention will be described in detail based on the illustrated embodiments.

It is a figure which shows the complex system schematicly. It is a figure which shows concretely the influence of a winding speed and a stop time. It is a figure which shows the operation unit of the complex system by this invention.

FIG. 1 shows a schematic view of a composite system 1 according to the present invention, which includes a ring spinning machine 2 and a winder 3.

An actual system often has a plurality of ring spinning machines 2 and a plurality of winders 3. Ring spinning machines produce cups. The working unit 4 of the winder 3 winds the cup into a large volume twill winding package. The ring spinning machine 2 and the winder 3 are connected to each other via a transfer system 5. The transport system 5 transports a full-tube cup from the ring spinning machine 2 to the winding machine 3, and transports an empty cup winding tube from the winding machine 3 to the ring spinning machine 2. The composite system 1 includes a control device 6 belonging to the winder 3. An operation unit 7 is connected to the control device 6 as an operation device. The operating device 7 enables parameter adjustment of the winder 3 and the transport system 5. In the illustrated embodiment, the operating device 7 includes a keyboard and a monitor. In addition, the monitor is configured as a touch screen for easier operation.

If a full-tube cup is present, the cup is wound into a twill-winding package in the working unit 4 of the winder 3. The work unit 4 is in the operating state "winding". When the last frying cup of the ring spinning machine runs out, the working unit 4 is stopped. In the operating state "stop", unnecessary consumers of the work unit 4 and the winder 3 are shut off. When the next frying cup of the ring spinning machine 2 is provided, the working unit 4 returns to the operating state "winding". The duration (or "stop time" for short) in the operating state "stop" has a great influence on the energy consumption of the winder 3.

The diagram in FIG. 2 clearly shows the effect of downtime on energy expenditure. The stop time is recorded on the horizontal axis 10. The vertical axis 11 represents the average value of the energy consumption or the total power of the winder for a complete single frying cup of the ring spinning machine 2. Curves 12, 13 and 14 show energy consumption at various winding speeds, respectively. Curve 12 shows the energy consumption at a predetermined take-up speed that results in continuous operation of the take-up machine 3. This winding speed corresponds to the boundary winding speed, and at this boundary winding speed, the fried cup is processed only when the next fried cup is provided. At lower speeds, productivity will be compromised. Therefore, at the speed based on curve 12, the downtime is zero. An operating point 12A is obtained on the curve 12 at zero stop time. Curve 13 is premised on a higher take-up speed than that of curve 12. Therefore, there is a stop time after winding the fried cup. That is, the operating point 13A on the curve 13 is located further to the right in the diagram.

As can be seen from the figure, relatively long downtime results in relatively low energy consumption. For curve 14, the take-up speed is further increased. The downtime is further increased, the operating point 14A moves further to the right, and the energy consumption is further reduced. In the case of the curve 15, the same winding speed as in the case of the curve 13 is assumed. Therefore, the downtime is still the same. Unlike the curve 13, with respect to the curve 15, yet another consumer is shut off in the operating state "stop". Specifically, here, the DC voltage intermediate circuit that supplies the voltage to the consumer is cut off. Therefore, further energy is saved. The operating point 15A is correspondingly located below the operating point 13A.

FIG. 3 shows a preferred embodiment of the operation unit 7 for adjusting the operation mode. The operating mode weights the quality of the twill winding package manufactured and the energy consumption during operation of the winder by adjusting the winding speed and the associated downtime adaptation of the working unit 4. Decreased energy consumption results in poor quality of manufactured twill-wrapped packages, and conversely, improved quality results in increased energy consumption. The operation unit 7 has a slide adjuster 8 including a slider 9. The slide adjuster 8 is preferably projected on the touch screen. The slider 9 allows for stepwise adjustment of the operating mode. Various positions 9'and 9 "of the slider 9 are illustrated.

Moving the slider from position 9 to position 9'reduces take-up speed and stop time, which in turn improves quality. Moving the slider from position 9 to position 9 "increases take-up speed and stop time. Energy consumption decreases.

Claims (4)

In a method of operating a composite system (1) consisting of at least one ring spinning machine (2) and at least one winder (3).
The cup is manufactured in the ring spinning machine (2), the cup is processed in the working unit (4) of the winder (3), and rewound into a twill winding package.
The winder (3) winds at a predetermined winding speed in the operating state "winding".
The work unit (4) of the winder (3) is stopped in the operating state "stop" to shut off unnecessary consumers of the winder (3).
The winder (3) is operated in the operating state "winding" in order to process the frying cup of the at least one ring spinning machine (2) in the winder (3).
The fried cup of the at least one ring spinning machine (2) has been processed in the winder (3), and the next fried cup of the at least one ring spinning machine (2) is still available. When not provided, the winder (3) is operated in the operating state "stop", and the winder (3) is operated in the operating state "stop".
At this time, a selection is made between at least one first operation mode and the second operation mode.
In order to achieve less energy consumption in the second operation mode than in the first operation mode, the take-up speed and the duration in the operation state "stop" are set in the second operation mode. Higher and longer than in the first operating mode, respectively,
In order to achieve higher quality of the manufactured twill winding package in the first operation mode than in the second operation mode, the winding speed and the operation state "stop" are performed in the first operation mode. A complex system (1) consisting of at least one ring spinning machine (2) and at least one winder (3) having a duration lower and shorter than that in the second operation mode, respectively, is operated. Method. The method according to claim 1, wherein the winding speed is made higher than the boundary winding speed, and at the boundary winding speed, the ball-fried cup is processed only when the next ball-fried cup is provided. .. In a winder (3) for a complex system comprising at least one ring spinning machine (2) configured to manufacture a cup.
The take-up machine (3) is provided with a control device, and a plurality of work units (4) of the take-up machine (3) are to process the cup and put the cup into a twill winding package. It is configured to rewind and
The winder (3) can be operated at a predetermined winding speed in the operating state "winding".
The work unit (4) of the winder (3) is stopped in the operating state "stop" to shut off unnecessary consumer machines of the winder.
The control device (6) sets the winder (3) in the operating state "winding" in order to process the ball-fried cup of the at least one ring spinning machine (2) in the winder (3). The at least one ring spinning machine (2) has been processed by the winder (3) and the at least one ring spinning machine (2) has been processed. When the next ball-fried cup of (2) is not yet provided, the winder (3) is configured to operate in the operating state "stop".
An operation device (7) is provided, and at least one first operation mode and a second operation mode can be selected by the operation device (7).
In order to achieve less energy consumption in the second operation mode than in the first operation mode, the take-up speed and the duration in the operation state "stop" are set in the second operation mode. Higher and longer than in the first operating mode, respectively,
In order to achieve higher quality of the manufactured twill winding package in the first operation mode than in the second operation mode, the winding speed and the operation state "stop" are performed in the first operation mode. The durations in "" are lower and shorter than in the second operation mode, respectively.
The control device (6) is a winder (3) for a composite system, which is configured to operate the winder in the operation mode selected in the operation device (7). The operating device (7) comprises means (8) for increasing or decreasing the winding speed in a stepwise manner to reduce energy consumption or improve the quality of the manufactured twill-wound package. The winder described in 3.

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