EP3741890A1 - Method for monitoring required air currents for handling a yarn and/or sliver and a spinning machine unit - Google Patents

Abstract

The invention relates to a method (100) for monitoring the air currents required for handling a thread and / or a sliver in a spinning machine with several spinning positions (3) and a spinning machine unit (1) for carrying out the method (100). The spinning machine is associated with at least one air flow generating source (6) which is connected to an air flow channel (7) in a communicating manner, the air flow channel (7) having a main air flow channel (8) and several of which are coupled to the source (6) air flow in a communicating manner Main air flow duct (8) has branching air flow ducts (9) each of which branches off to a spinning station (3) for supplying air to the spinning station's own handling units (4; 5) for handling a thread or a sliver. The spinning machine is assigned an evaluation device (13) for evaluating measurement data and a detection device (14) for detecting productive and / or non-productive spinning stations 83) and / or handling units (4; 5), the detection device (14) with the evaluation device (13) is connected for data transmission. The invention is characterized in that an air volume flow measuring unit (10) is provided which is located in the main air flow channel (8) between the source (6) and the air flow branch channel (9) next to the source (6) along the air flow path ) is arranged, wherein the air volume flow measuring unit (10) is connected to the evaluation device (13) for data transmission. The air volume flow is measured by means of the air volume flow measuring unit (10) and the measurement result is transmitted to the evaluation device (13). In addition, the number of productive and / or non-productive spinning positions (3) is recorded by means of the recording unit (14) at the time of the air volume flow measurement and transmitted to the evaluation device (13). An air volume flow setpoint is determined depending on the number of recorded productive and / or non-productive spinning stations (3) by means of the evaluation device (13), the air volume flow setpoint corresponding to a total air volume flow requirement of the productive spinning stations (3) at the time of measurement. The air volume flow target value is then compared with the actual value of the measured air volume flow by means of the evaluation device (13), the evaluation device (13) evaluating whether there is an impermissible deviation of the actual value from the air volume flow target value based on the comparison.

Description

The invention relates to a method for monitoring the air flows required for handling a thread and / or a sliver in a spinning machine having a plurality of spinning positions, and a spinning machine unit for carrying out the method.

As is known, spinning machines comprise a plurality of similar spinning positions which are equipped with handling units for handling a thread and / or a sliver, which at least occasionally require an air flow to handle the sliver in the course of the spinning process or the spun thread, in particular with a quality effect. The air flow is usually generated by at least one source which generates an air flow. Depending on the type of spinning machine, it can be a suction air system, which is used in particular in a rotor spinning machine, for example to generate a spinning vacuum, or a compressed air source, which is used in particular in an air-jet spinning machine to generate a spinning pressure.

The spinning rotor of the rotor spinning machine, the rotor cup of which is supplied with suction air during regular spinning operation, but also during a piecing process, can accordingly be regarded as a handling unit. In the case of an air-jet spinning machine, the spinneret can certainly be viewed as a handling unit. Generally all devices which pneumatically handle a thread or a sliver can be considered as handling units.

For the quality of the thread produced by the spinning machine, it is necessary that the air flow, in particular the associated pressure, negative pressure or volume flow, is in a defined range for the handling unit to handle the thread or the sliver properly. It further maximizes the productivity of the machine if the air flow is made available as soon as possible after a corresponding request, since otherwise the handling unit would have to spend an unproductive waiting time. On the other hand, the design of the source generating the air flow for a maximum required air flow requirement increases its costs in a disadvantageous manner. Similarly, maintaining an air flow above a level just needed increases energy consumption. This provision may be necessary, among other things, if there are losses within the air flow path, for example due to leaks.

It has therefore become established in the prior art, on the one hand, to accept certain waiting times for the air flow, at least in extreme situations, and, on the other hand, to regulate the air flow as precisely as possible to the required requirement. However, since regulation of the air flow is relatively sluggish, primarily due to the length of the air flow channels, the required air flow often cannot be maintained with purely tracking regulations.

Therefore, for example, with the publication DE 195 11 960 A1 Suggested that a handling unit has to register its airflow requirement in advance, i.e. should submit a request, whereupon the airflow control regulates it sufficiently in good time before the airflow is called up in order to maintain a sufficient airflow for all connected handling elements even after this request has been assigned. This can lead to increased energy consumption by increasing the required energy consumption. When a maximum permissible energy consumption is reached, further requests are no longer allocated, but the requesting handling unit is put on hold. Waiting handling units are only served again when the energy consumption has decreased sufficiently by processing previous requests.

With the print DE 10 2006 050 220 A1 a priority-controlled processing of the requirements is proposed. In particular, the waiting times for scarce resources such as the operating units responsible for several workplaces and the operating personnel can be shortened.

The pamphlet DE 10 2006 050 220 A1 discloses the distribution of the requirements of the handling units at the spinning station level. Specifically, allocations are only permitted to a certain number of spinning stations. If the maximum number is reached, requests for further handling units are placed in the queue. The air stream can consequently only be allocated to a waiting spinning station when one of the spinning stations that has just been supplied ends its work for which it had requested the air stream, so the spinning station no longer has any current demand.

All previously known solutions have in common that air flow losses due to, for example, leakages along the air flow path are not explicitly taken into account. Such losses can have such a negative effect on the functionality of the corresponding handling unit that an insufficiently applied air flow at the handling unit can lead to a loss of quality of the thread or sliver to be handled by the handling unit. For example, a spinning pressure or spinning vacuum that is too low can result in a lower quality thread. It should also be mentioned as an example that too low a pressure to compact the fibers of a sliver in the area of a drafting system of the spinning machine can also lead to a thread of inferior quality.

Against this background, the present invention is intended to provide a possibility of monitoring the air flows required for handling a thread and / or sliver and of detecting unwanted air flow losses, for example due to leaks, particularly simply and inexpensively. In the context of the present invention, an air flow is understood to mean an air flow generated by negative pressure via excess pressure, an air flow generated by negative pressure differing from the air flow generated by pressure only in the air flow direction.

To this end, according to a first aspect of the present invention, a method for monitoring the air flows required for handling a thread and / or a sliver in a spinning machine having a plurality of spinning positions is proposed. The spinning machine is assigned at least one source that generates an air flow and communicates with an air flow channel that guides the air flow, referred to below as the flow side, the air flow channel having a main air flow channel coupled to the source on the flow side and several air flow branch channels branching off from the main air flow channel. The air flow branch channels each branch off to a spinning station for supplying air to the spinning station's own handling units for handling the thread or the sliver. The spinning machine is also assigned an evaluation device for evaluating measurement data and a detection device for detecting productive and / or non-productive spinning stations and / or handling units, the detection device being connected to the evaluation device for data transmission. A data-transmitting connection can generally be implemented in the usual way as required, in particular in a wired or wireless manner.

The source, the evaluation device and / or the detection device can preferably be included in the spinning machine. Alternatively, the source, the evaluation device and / or the detection device can be arranged externally of the spinning machine and operatively connected to it, whereby a spinning machine unit is formed in the sense of the present invention.

The invention is characterized in that an air volume flow measuring unit is provided which is arranged in the main air flow channel between the source and the air flow branch channel closest to the source along the air flow path, the air volume flow measuring unit being connected to the evaluation device for data transmission in particular in a manner as described above. In the course of the method, the air volume flow is measured by means of the air volume flow measuring unit and the measurement result is transmitted to the evaluation device, for example in the form of a specific measured value or a code representing the measured value. Furthermore, the number of productive and / or non-productive spinning stations and / or handling units are recorded by means of the detection unit at the time of the air volume flow measurement and transmitted to the evaluation device. In a productive operation there is a spinning station or handling unit until it no longer requires an air flow to generate the thread or to handle the thread and / or sliver, for example because of a malfunction and the associated shutdown of the spinning station. Purely by way of example, processes defining a productive operation include piecing, spinning the thread, placing a thread end on an empty tube, compressing the sliver or the like. In all of these processes, air flows are required, using which the thread or the sliver is handled by appropriate handling units.

In the course of the method, an air volume flow target value is also determined depending on the number of productive and / or non-productive spinning positions recorded at the time of measuring the air volume flow, the air volume flow target value corresponding to a total air volume flow requirement of the spinning positions productive at the time of measurement. The determined air volume flow setpoint is compared with the actual value of the measured air volume flow and the comparison is evaluated as to whether there is an impermissible deviation of the actual value from the air volume flow setpoint. An impermissible deviation can exist, for example, when the setpoint defines a limit of a value range that is viewed as tolerable or permissible, the actual value of the measured air volume flow being outside the value range. Another impermissible deviation can exist if a difference value between the actual value and the setpoint value exceeds a specified, corresponding threshold value.

The processes of determination, comparison and evaluation are carried out by the evaluation device. For the purposes of the present invention, an evaluation device includes those functionally interacting elements or units which are designed to carry out these necessary processes. The elements or units can be separated from one another or implemented in a common assembly. The evaluation device can preferably a processor-based device such as a control unit assigned to one or more spinning machines or spinning stations.

As soon as an impermissible deviation has been assessed, an alarm signal can be initiated according to a preferred embodiment of the present invention. The alarm signal is initiated when the evaluation device transmits a signal suitable for triggering the alarm signal, for example directly to a unit triggering the alarm signal or to an intermediate unit. The alarm signal can be a visual, optical, acoustic and / or haptic signal. An operator of the spinning machine can use such an alarm signal to indicate improper operation of the spinning machine, in particular an air flow which is not correct for handling the thread or the sliver, which can lead to a thread of poor quality.

The proposed method provides an inexpensive and very simple option for monitoring air flows and, in particular, identifying air flow losses in a spinning machine.

The processes of measuring, transferring, determining, comparing and evaluating can be carried out continuously, periodically or at fixed times, depending on the energy consumption requirement. The more frequently such processes are carried out, the higher the corresponding energy requirement of the spinning machine can be, but the more reliable is the monitoring and the possibility of immediate intervention or troubleshooting, whereby the productivity of the spinning machine can be optimized

The method proposed by the invention is particularly suitable for a spinning machine configured as an air-jet spinning machine, the source generating an air flow being a compressed air source at least for generating a predetermined spinning pressure in a spinning unit or spinning nozzle of the spinning station.

According to a preferred embodiment, the alarm signal contains, in addition to the information about insufficient air flow supply, also the information in which spinning station section, more preferably which spinning station, further preferably which handling unit and / or air flow branch channel is affected. For this purpose, a further air volume flow measuring unit is preferably in at least one air flow branch duct, in particular in each air flow branch duct leading to a spinning station or directly to a handling unit arranged, wherein the further air volume flow measuring unit can in particular be assigned its own retrievable code for identifying the spinning station or the handling unit or the air flow branch duct. At a specified point in time, the air volume flow is measured by the additional air volume flow measuring unit and transmitted to the evaluation device. At the point in time of the air volume flow measurement, the detection unit records whether the spinning station or handling unit that is operatively connected to the further air flow measuring unit is productive and / or not productive. A corresponding individual actual value of the measured air volume flow is assigned to the productive spinning station or handling unit and is compared with an individual setpoint value which corresponds to a total air volume flow requirement of the actively connected spinning station or handling unit. Based on the comparison, the evaluation device makes an assessment as to whether there is an impermissible deviation of the individual actual value from the individual setpoint. In the event that a deviation is assessed as inadmissible, an alarm signal is initiated which includes information about the additional air volume flow measuring unit, spinning station, handling unit and / or air flow branch channel relating to the inadmissible deviation.

The air flow branch duct further preferably has a closure element for closing the air flow branch duct, particularly preferably near the branch from the main air flow duct. The closure element can preferably be moved manually and / or automatically between an open position for the passage of the air volume flow and a closed position for the closure of the air flow branch duct. By means of such a closure element, if there is an impermissible deviation, only the spinning station or handling unit which is affected by the air flow loss needs to be shut down or disconnected from the air flow supply. The other spinning stations or handling units can continue to be operated properly.

According to a further aspect of the present invention, a spinning machine unit for carrying out a method according to one of the preferred embodiments is proposed.

The spinning machine unit comprises several spinning stations, each with at least one handling unit requiring an air flow for handling a thread or sliver by means of the required air flow. Furthermore, the spinning machine unit has a source which generates an air flow and which communicates with an air flow channel, referred to as the flow side in the following, the air flow channel having a main air flow channel coupled to the source on the flow side and a plurality of the main air flow channel having branching air flow branch channels each branching off to a spinning station for the air flow supply of the at least one spinning station-own handling unit. The spinning machine unit further comprises an evaluation device for evaluating measurement data and a detection device for detecting productive and / or non-productive spinning positions, the detection device being connectable or connected to the evaluation device in a data-transferring manner.

The spinning machine unit is characterized in that an air volume flow measuring unit is provided, which is arranged in the main air flow channel between the source and the air flow branch channel closest to the source along the air flow path, the air volume flow measuring unit being connectable or connected to the evaluation device for data transmission. The air volume flow measuring unit can be arranged in a preferred manner in a machine end or center frame, from which the arrangement of the multiple spinning stations takes place. The machine end or center frame can have a control housing with units for controlling and / or regulating the assigned spinning positions, in which the air volume flow measuring unit is preferably accessible and more preferably arranged outside the control housing, for example through a viewing window or opening.

Furthermore, the evaluation device is set up to determine an air volume flow target value depending on the number of productive and / or non-productive spinning positions recorded at the time of measuring the air volume flow, the air volume flow target value corresponding to a total air volume flow requirement of the productive spinning positions at the measurement time. The evaluation device is also set up to compare the air volume flow target value with the actual value of the measured air volume flow and, based on the comparison, to make an assessment of whether there is an impermissible deviation of the actual value from the air volume flow target value.

With such a spinning machine unit, the advantages associated with the proposed method according to a preferred embodiment of the present invention can also be achieved. The components assigned to the spinning machine unit can preferably be developed accordingly in such a way that the steps or processes described in the course of the method according to a preferred embodiment can be carried out and carried out by the respective component.

According to a preferred embodiment, there is preferably a further air volume flow measuring unit in at least one air flow branch duct, in particular in each to a spinning station or the air flow branch duct leading directly to a handling unit, the detection device being set up to detect at a point in time of an air flow measurement carried out by the further air flow measuring unit whether the spinning stations or handling unit that are actively connected to the further air flow measuring unit are productive and / or non-productive. In this context, the evaluation device is set up to assign an individual actual value of the measured air volume flow to the productive spinning station or handling unit that is actively connected to the further air volume flow measuring unit and to compare it with a corresponding individual setpoint value which corresponds to a total air volume flow requirement of the actively connected spinning station or handling unit. Based on the comparison, the evaluation device is also set up to evaluate whether there is an inadmissible deviation of the individual actual value from the individual nominal value and, if a deviation is assessed as inadmissible, to initiate an alarm signal which provides information about the additional air volume flow measuring unit relating to the inadmissible deviation , Spinning station, handling unit and / or air flow branch channel.

Furthermore, according to one embodiment, a closure element is arranged in the air flow branch duct, which comprises a further air volume flow measuring unit, which can be moved between an open and closed position, the closure element being in the closed position to shut off the air flow supply to the associated spinning station and / or handling unit if a deviation relating to the air flow branch duct having the closure element was assessed as inadmissible.

Further features and advantages of the invention emerge from the following description of preferred exemplary embodiments of the invention, with reference to the figures and drawings, which show details essential to the invention, and from the claims. The individual features can each be implemented individually or collectively in any combination in a preferred embodiment of the invention.

Preferred embodiments of the invention are explained in more detail below with reference to the accompanying drawings.

Fig. 1

schematisch eine Spinnmaschineneinheit nach einem bevorzugten Ausführungsbeispiel; und

Fig. 2

schematisch ein Ablaufdiagramm eines Verfahrens nach einem bevorzugten Ausführungsbeispiel.

Show it

Fig. 1

schematically a spinning machine unit according to a preferred embodiment; and

Fig. 2

schematically a flow chart of a method according to a preferred embodiment.

Figure 1 shows in a purely schematic representation a spinning machine unit 1 according to a preferred embodiment, which is suitable for carrying out a method 100 according to a preferred embodiment, which is with the Figure 2 is shown schematically illustrated flow chart.

The spinning machine unit 1, which is, for example, a rotor spinning machine or air-jet spinning machine, comprises at one end of the machine a machine frame with a control housing 2, from which a plurality of spinning stations 3 extend on and along a machine longitudinal side of the spinning machine unit arranged in rows, the respective spinning stations 3 with one in the Control housing 2, not shown, central control unit are connected on the data transmission side. Each spinning station 3 has first 4 and second handling units 5 for handling a thread or sliver to be handled at the respective spinning station 3. The first 4 and second handling units 5, depending on the type of spinning machine, can be conventional units that are assigned to a respective spinning position 3 and require an air flow for handling a thread or sliver, such as spinning rotors, pneumatic thread stores, spinnerets, compression devices or the like.

The spinning machine unit 1 comprises a source 6 which generates an air flow and which in this preferred exemplary embodiment is arranged in the control housing 2. The source 6 is set up to generate an air flow caused by underpressure or overpressure. The source 6 is connected to an air flow channel 7 communicating air flow, hereinafter referred to as the flow side, wherein the air flow channel 7 has a main air flow channel 8 and several air flow branch channels 9 branching off therefrom. Each of the branching air flow branch ducts 9 leads to a spinning station 3 and the first 4 and second handling units 5 assigned to the spinning station 3 in order to supply them with the air stream that can be generated by the source 6.

The main air flow channel 8 has an air volume flow measuring unit 10 in an air flow branch channel 9 next between the source 6 and one of the source 6, which air volume flow measuring unit 10 is arranged in the control housing 2 according to the preferred exemplary embodiment shown. The air volume flow measuring unit 10 can be accessed in the control housing 2 through a maintenance flap and, in particular, can be seen through a viewing window integrated in the maintenance flap. According to a preferred exemplary embodiment, the air volume flow measuring unit 10 can have a display for scaled and / or digital display of the measurable air volume flow passed through.

The respective air flow branch duct 9 leading to a spinning station 3 and the air flow branch ducts 9 leading from it to a respective first 4 and second handling unit 5 have a further air volume flow measuring unit 11 for measuring the air volume flow passed through. A closure element 12, for example in the form of a controllable valve, is arranged along the air flow path between the main air flow channel 8 and the air flow branch channel 9. The closure element 12 can be moved between an open and closed position. In the open position, an air flow can be passed through the corresponding air flow branch duct 9 via the closure element 12, whereas the corresponding air flow branch duct 9 is blocked for the air flow when the closure element 12 is in the closed position. The intermediate arrangement of the closure element 12 between the further air volume flow measuring unit 11 and the main air flow channel 8 is advantageous in that, in the respective open and closed position, a measurement can be used to check whether the further air flow branch channel 9 can be supplied or sealed off with the air flow.

The air volume flow measuring unit 10, the further air volume flow measuring units 11 and the closure elements 12 are connected to an evaluation device 13 on the data transmission side. In this way, air volume flows measured by the air volume flow measuring unit 10 and the further air volume flow measuring units 11 can be transmitted to the evaluation device 13. Furthermore, the respective closure element 12 can be activated for bringing it into the open or closed position. Even if in the block diagram the Figure 1 the data transmission path is shown monodirectional, so according to a further preferred embodiment it can be a bidirectional connection, in particular to be able to give or retrieve corresponding feedback.

The evaluation device 13 is also connected to a detection device 14 on the data transmission side in a mono- or bidirectional manner. According to this preferred exemplary embodiment, the detection device 14 is in turn connected on the data transmission side in a mono- or bidirectional manner to a respective spinning station 3 and a respective first 4 and second handling unit 5. In this context it should be emphasized that in the Figure 1 purely for the sake of clarity, only the data transmission-side connection of the next spinning station 3 along the air flow path of the source 6, the first handling unit 4, closure elements 12 and further air volume flow measuring units 11 is shown. A corresponding connection applies in an equivalent manner to the rest, in the Figure 1 unconnected components shown.

The detection device 14 is set up to detect a productive and / or non-productive spinning station 3, first 4 and second handling unit 5 and to transmit it to the evaluation device 13.

The above-described spinning machine unit 1 according to a preferred embodiment is set up with the Figure 2 Method 100, shown schematically as a flowchart, for monitoring the air flows required for handling a thread and / or a sliver according to a preferred exemplary embodiment. The method 100 comprises a step 110 of measuring an air volume flow by means of the air volume flow measuring unit 10, which is arranged in the main air flow channel 8. The measured value measured at a defined point in time or a coding value depicting this is transmitted to the evaluation device 13. At the defined point in time of the measurement, the number of productive and / or non-productive spinning stations 3 is recorded in a further step 120 and transmitted to the evaluation device 13. Subsequently, in a further step 130, the evaluation device 13 is used to determine an air volume flow setpoint depending on the number of recorded productive and / or non-productive spinning positions 3, the air volume flow setpoint corresponding to a total air volume flow requirement of the productive spinning positions at the time of measurement. The total air volume flow requirement is a theoretical value and corresponds to such an air volume flow which is necessary for the proper operation of the productive spinning stations. For the proper operation of a productive spinning station, an individual setpoint value is usually known or can be determined in advance, this value generally depending on the design of the respective spinning station. This value can be called up by the evaluation device 13 in a volatile or non-volatile memory (not shown) and can be stored in a changeable manner by an operator or a control unit. The memory is assigned at least to the spinning machine and can in particular be comprised of this. According to a preferred exemplary embodiment, the individual target value is multiplied by the number of productive spinning stations in order to obtain the air volume flow target value. Alternatively, a concordance table comprising a respective air volume flow setpoint value for a respective different number of productive spinning positions can be stored in the memory such that an air volume flow setpoint value can be called up directly depending on the number of productive spinning positions. The number of productive spinning positions can take place directly by recording the productive spinning positions or by recording the non-productive spinning positions, the latter having a step of calculating a known total number connected to the main air flow channel Spinning positions minus the recorded number of non-productive spinning positions.

In a subsequent step 140, the evaluation device 1 compares the determined air volume flow target value with the actual value of the measured air volume flow and subsequently or in the course of the comparison makes an assessment in a further step 150 as to whether there is an impermissible deviation of the actual value from the air volume flow target value present. If an impermissible deviation is assessed as being present, the evaluation device 13 initiates an alarm signal, by means of which the impermissible deviation can be displayed to an operator, for example via an alarm signal display unit 15 which is connected to the evaluation device 13 for data transmission (cf. Figure 1 ).

According to a preferred exemplary embodiment, the above steps can take place continuously or, according to an alternative exemplary embodiment, at fixed times, in particular periodically. An air volume flow loss in the air flow duct can be identified in a simple manner by means of the monitoring. Depending on the number of spinning stations, the spinning machine unit can definitely have more than one air flow duct, one air flow duct being provided to supply a defined number of spinning stations. In this way, the location of the loss of the air volume flow can be determined more closely depending on the air flow channel in which an impermissible deviation has been assessed.

At the with Figure 1 According to a preferred exemplary embodiment, further air volume flow measuring units 11 and closure elements 12 are provided which are arranged in the air flow branch ducts 9.

Equivalent to the above-described monitoring of the main air flow duct 8, an air flow branch duct 9 can also be monitored for an unusual loss of air volume flow, such as a leak. For this purpose, in a step 160 the air volume flow is measured by means of a further air volume flow measuring unit 11 and transmitted to the evaluation device 13. At the time of the measurement, the detection unit 14 detects the productive and / or non-productive spinning stations 3 and / or first 4 and second handling units 5 in a step 170. In a step 180, the detected productive spinning stations and / or handling units receive a corresponding measured individual actual value of the measured air volume flow or vice versa in order to be able to compare in a further step 190 with a corresponding individual setpoint, the individual setpoint corresponding to an air volume flow requirement of the respective operatively connected spinning station or handling unit. Based on the comparison, an evaluation takes place in the course of a step 200 by means of the evaluation device 13, whether there is an impermissible deviation of the individual actual value from the individual setpoint. In the event that a deviation is assessed as impermissible, an alarm signal is initiated in a step 210 by means of the evaluation device, which includes information about the additional air volume flow measuring unit, spinning station, handling unit and / or air flow branch duct relating to the impermissible deviation, which makes it even easier to localize the impermissible deviation is made possible. Furthermore, if a deviation is assessed as impermissible, the air flow branch duct 9 relating to the impermissible deviation is sealed off from the air flow supply by moving the closure element 12 from the open position into the closed position in a step 220. As a result, other spinning stations or handling units that are not connected to the air flow branch duct 9 and require the air flow can continue to operate properly and at the same time the affected air flow branch duct 9 can be examined for the reasons for the impermissible deviation.

The provision of further air volume flow measuring units 11 and / or closure elements 12 in air flow branch ducts 9 of the spinning machine unit 1 can take place as required. Thus, only further air volume flow measuring units 11 or only closure elements 12 can be arranged in selected air flow branch ducts 9. The method 100 described above can also be suitably adapted depending on an arrangement of further air volume flow measuring units 11 and / or closure elements 12. The respective process steps or selected ones of them can be carried out for an air flow branch duct 9 and / or air flow main duct 8 or for several air flow branch ducts 9 and / or air flow main ducts 8 in order to be able to determine air volume flow losses in the respective air flow branch ducts 9 and / or air flow main ducts 8.

List of reference symbols

1

Spinning machine unit

2

Control housing

3

Spinning position

4th

first handling unit

5

second handling unit

6

Air flow generating source

7th

Airflow duct

8th

Main airflow duct

9

Air flow branch duct

10

Air volume flow meter

11

further air volume flow measuring unit

12

Closure element

13

Evaluation device

14th

Detection device

15th

Alarm signal display unit

100

Procedure

110

Step of measuring an air volume flow by means of the air volume flow measuring unit

120

Step of detecting the productive and / or non-productive spinning positions

130

Step of matching

140

Step of evaluating

150

Step of initiating an alarm signal

160

Step of measuring an air volume flow by means of the further air volume flow measuring unit

170

Step of detecting the productive and / or non-productive spinning stations and / or handling units

180

Step of mapping

190

Step of comparing the individual setpoint with the individual actual value

200

Step of evaluating

210

Step of initiating an alarm signal

220

Step of locking

Claims (8)

Method (100) for monitoring the air flows required for handling a thread and / or a sliver in a spinning machine having several spinning positions (3),
the spinning machine being assigned at least one air flow generating source (6) which is connected to an air flow channel (7) in a communicating manner, the air flow channel (7) having a main air flow channel (8) communicating with the source (6) air flow and a plurality of the air flow branch ducts (9) branching off the main air flow duct (8) and each branching off to a spinning station (3) for supplying air to the spinning station's own handling units (4; 5) for handling a thread or a sliver, and
wherein the spinning machine is assigned an evaluation device (13) for evaluating measurement data and a detection device (14) for detecting productive and / or non-productive spinning stations 83) and / or handling units (4; 5), the detection device (14) with the Evaluation device (13) is connected to transmit data,
characterized in that
an air volume flow measuring unit (10) is provided, which is arranged in the main air flow channel (8) between the source (6) and the air flow branch duct (9) next to the source (6) along the air flow path, the air volume flow measuring unit (10) with the evaluation device (13 ) is connected for data transmission,
in a step (110) the air volume flow is measured by means of the air volume flow measuring unit (10) and the measurement result is transmitted to the evaluation device (13),
in a step (120) the number of productive and / or non-productive spinning stations (3) is detected by means of the detection unit (14) at the time of the air volume flow measurement and transmitted to the evaluation device (13),
In a step (130), an air volume flow target value is determined as a function of the number of productive and / or non-productive spinning positions (3) recorded at the time of measuring the air volume flow, the air volume flow target value relating to a total air volume flow requirement of the spinning positions productive at the measurement time (3 ) corresponds,
in a step (140) the air volume flow setpoint is compared with the actual value of the measured air volume flow by means of the evaluation device (13), and
In a step (150) the evaluation device (13), based on the comparison, carries out an assessment of whether there is an inadmissible deviation of the actual value from the air volume flow target value. Method (100) according to Claim 1, characterized in that an alarm signal is initiated by the evaluation device (13) if the evaluation results in an impermissible deviation of the actual value from the nominal value. The method (100) according to claim 1 or 2, characterized in that the spinning machine is an air-jet spinning machine, the source generating an air flow being a compressed air source at least for generating a predetermined spinning pressure in a spinning unit of the spinning station (3). Method (100) according to one of the preceding claims, characterized in that a further air volume flow measuring unit (11) in at least one air flow branch duct (9), in particular in each air flow branch duct (3) leading to a spinning station (3) or directly to a handling unit (4; 5). 9) is arranged, wherein in a step (160) the air volume flow is measured at a specified time by the further air volume flow measuring unit (11) and transmitted to the evaluation device (13), in a step (170) at the time of the air volume flow measurement by means of the Detection unit (14) detects whether the spinning station (3) or handling unit (4; 5) that is operatively connected to the further air flow measuring unit (11) is productive and / or non-productive, with the operatively connected productive spinning station (3) in a step (180) or handling unit (4; 5) assigned a corresponding individual actual value of the measured air volume flow and in one step t (190) is compared with an individual setpoint value, which corresponds to a total air volume flow requirement of the operatively connected spinning station (3) or handling unit (4; 5) corresponds, whereby in a step (200) based on the comparison an evaluation is carried out by means of the evaluation device (13) as to whether there is an inadmissible deviation of the individual actual value from the individual nominal value and, in the case of the evaluation of a deviation as impermissible, in one step (210) an alarm signal is initiated by the evaluation device (13), which includes information about the inadmissible deviation related further air volume flow measuring unit (11), spinning station (3), handling unit (4; 5) and / or air flow branch duct (9). Method (100) according to claim 5, characterized in that in each air flow branch duct (9) comprising a further air volume flow measuring unit (11) a closure element (12), in particular near the main air flow duct (8), is arranged, which can be moved between an open and closed position is, wherein the closure element (12) is moved into the closed position when one of the closure element (12) having Air flow branch duct (9) was assessed as impermissible. Spinning machine unit (1) for carrying out a method (100) according to Claim 1, characterized in that the spinning machine unit (1) comprises
several spinning stations (3) each with at least one handling unit (4; 5) requiring an air flow for handling a thread or sliver by means of the required air flow,
a source (6) generating an air flow which is connected in a communicating manner to an air flow duct (7), the air flow duct (7) having a main air flow duct (8) which is coupled to communicate with the air flow source (6) and several of the main air flow duct (8) having branching air flow branch ducts (9) which each branch off to a spinning station (3) for supplying air to the at least one spinning station's own handling unit (4; 5),
an evaluation device (13) for evaluating measurement data, and
a detection device (14) for detecting productive and / or non-productive spinning stations (4; 5), the detection device (14) being connectable or connected to the evaluation device (13) in a data-transferring manner,
characterized in that
an air volume flow measuring unit (10) is provided, which is arranged in the main air flow channel (8) between the source (6) and the air flow branch duct (9) next to the source (6) along the air flow path, the air volume flow measuring unit (10) with the evaluation device (13 ) is connectable or connected for data transmission, and
the evaluation device (13) is set up, - to determine an air volume flow target value depending on the number of productive and / or non-productive spinning positions (3) recorded at the time of measuring the air volume flow, the air volume flow target value corresponding to a total air volume flow requirement of the productive spinning positions (3) at the measurement time, - compare the air volume flow setpoint with the actual value of the measured air volume flow, and - based on the comparison, make an assessment of whether there is an impermissible deviation of the actual value from the air volume flow setpoint. Spinning machine unit (1) according to claim 6, characterized in that a further air volume flow measuring unit (11) is in at least one air flow branch duct (9), in particular in each to a spinning station (3) or directly to a handling unit (4; 5) leading air flow branch duct (9) is arranged,
wherein the detection device (14) is set up to detect at a point in time of an air volume flow measurement carried out by the further air flow measuring unit (11) whether the spinning station (3) or handling unit (4; 5) operatively connected to the further air flow measuring unit (11) is productive and / or is not productive,
wherein the evaluation device (13) is set up - to assign an individual actual value of the measured air volume flow to the productive spinning station (3) or handling unit (4; 5) that is actively connected to the further air volume flow measuring unit (11) and to compare it with a corresponding individual setpoint value which results in a total air volume flow requirement of the actively connected spinning station (3) or handling unit ( 4; 5) corresponds, - based on the comparison, make an assessment of whether there is an impermissible deviation of the individual actual value from the individual setpoint, and - In the event that a deviation is assessed as impermissible, an alarm signal is initiated which includes information about the additional air flow measuring unit (11), spinning station (3), handling unit (4; 5) and / or air flow branch duct (9) relating to the impermissible deviation. Spinning machine unit (1) according to claim 7, characterized in that in the air flow branch duct (9) comprising a further air volume flow measuring unit (11) a closure element (12), in particular near the main air flow duct (8), is arranged, which can be moved between an open and a closed position is, the closure element (12) being in the closed position when a deviation relating to the air flow branch duct (9) having the closure element (12) has been assessed as inadmissible.

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