WO2022148637A1 - Method for determining the noil quantity on a combing machine and combing machine - Google Patents

Abstract

The invention relates to a method for determining the noil quantity on a combing machine having a plurality of combing heads (20), wherein at least one lap strip (4) unwinds from a lap roll (1) at each combing head (20) and is fed by means of a feed cylinder (26) to a nipper assembly (27), the noils are combed and removed by suction from the lap strip (4) by means of a fixed and cylindrical comb (33, 38), and the fibre web created is formed by means of a sliver trumpet (41) into a fibre strip (F1 – Fn), which is drawn with the other fibre strips from the other combing heads to a single fibre strip (F), wherein the weight of the lap roll on the combing head and the strip mass of all combed fibre strips before the coiler is determined. The invention is characterized in that the weight of the lap roll or the change in weight over the length of the unwound lap strip (4) or over a specified time (m) is converted into an incoming strip mass in a control unit (S) and the outgoing strip mass determined by the sensor is subtracted from this strip mass to be combed and the quantity of noils combed out is indicated on an output device (A).

Description

Title: Procedure for determining the amount of noils on a combing machine and combing machine

description

The invention relates to a method for determining the quantity of noils on a combing machine, and a combing machine with a plurality of combing heads, with at least one lap sliver being unwound from a lap roll on each combing head, being fed to a gripper unit by means of a roller and a feed cylinder, and the noils being picked up by means of a fixed and circular comb are combed out of the batting sliver and sucked off, and the resulting fiber web is formed into a sliver by means of a sliver funnel, which is stretched with the other slivers of the other combing heads to form a single sliver, with the sliver mass of all combed slivers being determined before the can coiler.

The quality of a yarn is determined, among other things, by a high proportion of long fibers, since short fibers give the yarn less strength. In preparation for the spinning mill, the short fibers can be combed out by a combing machine. Round and top combs separate short fibres, neps, trash and dust from the previously connected fibres. A high proportion of waste, also known as noils, can be an indication of good yarn quality in the future. However, it can also be an indication of poor fiber feed, which has a disproportionately high proportion of short fibers, neps, trash and dust that must first be removed. Furthermore, a high number of noils can be an indication of an incorrect setting or of defects on the machine. In the spinning preparation, the amount of noils should be determined as precisely as possible, since the disposed amount of short fibers is ultimately an expensive waste product. Various systems are known in practice for determining noils, which are recorded with different effort by means of sensors or whose mass is weighed. WO 93/12278 A1 discloses the arrangement of sensors for detecting the combed-out noils for each separate combing head or for all noils of the combing machine. DE 102006002390 A1 describes the associated setting options of the combing machine depending on the fiber quality.

In DE 102007039067 A1, each combing head of a combing machine has sensors with which the weight of a lap roll is measured in front of the combing head. The combed out noils are removed via suction under the circular comb. After the combing head, the output mass is measured using a measuring funnel or sensor and compared with the input mass. A controller compares the measurement data, with the difference in mass corresponding to the noils combed out. The controller can change the proportion of Display noils for each combing head separately or for the entire combing machine and use this to influence the setting of the combing machine.

According to EP 3030702 B1, the circular comb and the cleaning brush of the circular comb are arranged in a vacuum-extracted channel which pulls off the combs. The number of noils can be determined by means of a sensor.

WO 2016/067155 A1 discloses several sensors with which the proportion of noils on the circular comb and thus the combing intensity or the cleaning intensity of a brush roller is monitored.

A disadvantage of this prior art is that a separate measuring device for determining the initial mass is arranged for each combing head, which can be very complex and also prone to errors.

Proceeding from this known state of the art, it is the object of the invention to provide a method and a device for detecting noils on the combing machine, which is of simple and inexpensive construction. The invention is solved by the features of claim 1, 2 and claim 11 and 12. Advantageous developments are defined in the dependent claims.

The invention relates to a method for determining the amount of noils on a combing machine with several combing heads, with at least one lap sliver being unwound from a lap roll on each combing head, being fed to a gripper unit by means of a feed cylinder, the noils being combed out of the lap sliver and sucked off by means of fixed and circular combs , and the resulting fibrous web is formed into a sliver by means of a sliver funnel, which is stretched with the other slivers of the other combing heads to form a single sliver, with the sliver mass of all combed slivers being determined before the can coiler. The invention includes the technical teaching that the sliver mass of all lap laps entering the combing machine, the number of combing cycles, the tensioning delay of the lap sliver and the feed amount are entered manually by means of an input device and converted into a sliver mass to be combed in a controller, wherein the controller subtracts the outgoing sliver mass determined by the sensor from this sliver mass to be combed and displays the quantity of combed noils by means of an output device.

According to the invention, the method and the associated combing machine have a simpler structure than in the prior art. In particular, the measuring devices after each combing head omitted and only the total sliver mass (initial mass) of the sliver F at the sliver funnel is determined. This is a mathematical determination of the noil percentage, which is based, among other things, on the target values for the winding count. If the winding count deviates from the target values or if the fiber mass entering the comber deviates, the tensioning draft can be changed. Since the input mass is calculated and the output mass of the fibers is precisely determined by means of a sensor, the determination of the noils is sufficiently accurate so that the measuring device only has to be calibrated once with little effort. Production data such as the number of comb cycles, tensioning delay, delivery speed and sliver count are routinely recorded on the comber and automatically used to calculate the noils. In comparison to the prior art, only the control of the combing machine has to be designed to calculate the quantity of noils. After this procedure, the values for the incoming belt mass are entered manually into the control.

In the same way, the invention also provides a method for determining the quantity of noils on a combing machine with a plurality of combing heads, with at least one lap sliver being unwound from a lap roll on each combing head, being fed to a nipper unit by means of a feed cylinder, the noils being removed by means of fixed and circular combs are combed out of the lap sliver and sucked off, and the resulting fiber web is formed into a sliver by means of a sliver funnel, which is stretched with the other slivers of the other combing heads to form a single sliver, with the weight of the lap rolls on the combing head and the sliver mass of all combed slivers before the can deposit is determined.

Such a method is characterized in that within a controller, the weight of the lap roll or the change in weight over the unwound length of the

Wadding sliver or is converted over a certain time into an incoming sliver mass and from this sliver mass to be combed the outgoing sliver mass determined by the sensor after the drafting system is subtracted and the quantity of combed-out noils is displayed by means of an output device. Also the outgoing one determined after the drafting system

Sliver mass is determined over the length of the sliver or over a certain period of time.

According to this method, the values for the incoming strip mass are only partly entered manually into the control, or are automatically determined by the control. Will the

If the winding fineness is entered manually into the control, this has the advantage, in combination with the determination of the winding weight over the length of the unwound wadding, that immediately

Band mass fluctuations are detected at the entrance of the comber and by means of a

Delay device can be compensated. The amount of fibers to be combed out is thereby more uniform and the combed sliver has a higher quality than in the prior art. At the same time, if there are fluctuations in the number of noils, errors on the machine (e.g. a broken top comb) or quality defects on the lap feed can be detected very quickly. According to the invention, the device and the method have a simpler structure than in the prior art. In particular, the measuring devices after each combing head are omitted and only the total sliver mass (initial mass) of the sliver is determined at the sliver funnel or after the drafting system before the can coiler. Using the data from the sensors, with which the weight of the lap roll is determined, fluctuations in sliver mass at each combing head can be determined by means of the controller at short time intervals, which can be directly compensated for by the tensioning distortion of the lap sliver.

Preferably, the number of comb games and the stretching delay of the lap sliver can be entered manually by means of an input device.

In an advantageous embodiment, the weight of the lap rolls can be determined at each combing head. This means that fluctuations in sliver mass can be recorded at each combing head and compensated for, for example, by adjusting the draft.

However, it can also be sufficient to determine the combined weight of the lap rolls of a group of combing heads. This means that fluctuations in sliver mass cannot be detected at the individual combing heads. However, if this is to be part of the combing process, the combed sliver mass can be determined after each combing head with a sensor which can be arranged in the sliver funnel with which the fibrous web is formed into a sliver. In this variant, too, fluctuations in the fiber mass to be combed can be compensated for at each combing head by changing the tension draft.

Preferably, the quantity of noils combed out can be changed by adjusting machine parameters such as the insertion depth of the top comb, changing the eccentricity and/or changing the number of comb cycles.

The combing machine according to the invention has a plurality of combing heads, with at least one lap sliver being unwound from a lap roll on each combing head and fed to a gripper unit by means of a roller and a feed cylinder. The noils are combed out of the batting sliver with a top and round comb and sucked off, and the resulting fibrous web is formed into a sliver using a sliver funnel. These individual slivers are stretched with the other slivers of the other combing heads to form a single sliver, the weight of the lap roll on the combing head and the sliver mass of all combed slivers before the can coiler is determined by sensors.

In a first embodiment of the invention, the combing machine is characterized in that the sliver mass of all lap laps entering the combing machine, the number of combing cycles, a tensioning delay of the lap sliver, and the feed amount are entered manually by means of an input device, and a controller is designed to process the entered data converted to a sliver mass to be combed, the controller subtracting the outgoing sliver mass determined by the sensor from this sliver mass to be combed and displaying the quantity of noils combed out by means of an output device. Advantageously, the combing machine has a simpler structure than in the prior art. In particular, the measuring devices after each combing head are omitted and only the total sliver mass (initial mass) of the sliver F at the sliver funnel is determined. This is a mathematical determination of the noil percentage, which is based, among other things, on the target values for the winding count. If there is a deviation from the target values for the winding count or the fiber mass entering the comber, the tension draft can be changed. Since the input mass is calculated and the output mass of the fibers is precisely determined by means of a sensor, the determination of the noils is sufficiently accurate so that the measuring device only has to be calibrated once with little effort. Production data such as the number of comb cycles, tensioning delay, delivery speed and sliver count are routinely recorded on the comber and automatically used to calculate the noils. The combing machine differs from the prior art in terms of the control system, which can determine the quantity of noils by calculating the incoming sliver mass by subtracting the measured outgoing sliver mass. The advantage for the customer is that the quantity of noils no longer has to be weighed manually, but that conclusions about the operation of the comber and the quality of the combed sliver are possible through a continuous display of the noil quantity.

In a second embodiment of the invention, the combing machine is characterized in that a controller is designed to process the sensor data by converting the weight of the lap roll or the change in weight over the unwound length of the lap sliver or alternatively over a specific time into an incoming sliver mass and from this sliver mass to be combed, the outgoing sliver mass determined by the sensor is subtracted and, as a result, the quantity of noils combed out is displayed by means of an output device. The outgoing sliver mass determined by the sensor can also be based on the length of the sliver or on the sliver mass per units of time are converted. With this second embodiment according to the invention, a semi-automatic or fully automatic determination of the number of noils is possible.

Each combing head preferably has a sensor for determining the weight of the lap roll. Alternatively, a group of combing heads can have a sensor for determining the combined weight of the lap rolls.

A sensor for determining the sliver mass can preferably be arranged after each combing head on the sliver funnel with which the fibrous web is formed into a sliver. In combination with the one weight sensor for the group of combing heads, the fluctuation in sliver mass per combing head can nevertheless be determined and/or a sliver break can be detected.

At least one lap transport roller is preferably driven. Two lap transport rollers are preferably driven. The lap sliver can be conveyed smoothly into the combing head via the driven lap transport rollers. A tightening delay can preferably be set by changing the speed of the at least one driven lap transport roller and/or the speed of the feed roller. In this way, fluctuations in the incoming sliver mass before the combing process can be compensated to a limited extent.

A tensioning draft can preferably be produced on the lap sliver by means of a drafting device which is arranged between the lap transport rollers and the feed roller.

In a further advantageous embodiment, the diameter and the speed of the lap transport rollers can be used to control the lap weight over the lap length. In addition, the current lap weight for each lap is determined via the sensors on the combing head via the unwound length of each lap or over time, with the diameter and the speed of the driven lap transport rollers being used in the control for the unwound length of each lap. The incoming fiber mass per unwound lap length can thus be determined for each lap, with which fluctuations in the lap weight can be recorded and compensated for via the tensioning delay between the roller and the feed cylinder. Further measures improving the invention are presented in more detail below together with the description of a preferred exemplary embodiment of the invention with reference to the figures.

Show it:

1 shows a schematic side view of a combing head of a combing machine;

2 shows a schematic plan view of a combing machine;

3 shows a first exemplary embodiment of the noil measurement on the combing machine;

4 shows a further schematic side view of a combing head of a combing machine;

5 shows a schematic plan view of a combing machine;

6 shows a second exemplary embodiment of the noil measurement on the combing machine; 7 shows a third exemplary embodiment of the noil measurement on the combing machine.

Preferred embodiments of the combing machine K according to the invention are explained below with reference to FIGS. The same features in the drawing are each provided with the same reference symbols. At this point, it goes without saying that the drawing is merely simplified and, in particular, is shown without scale.

FIG. 1 shows a combing head 20, of which at least eight are mounted on a combing machine. For the sake of clarity, the exemplary embodiment is shown and described using only one combing head 20, with the details shown being installed on each of these combing heads except for the common drive units and the sliver coiler. The combing head 20 consists, among other things, of two lap transport rollers 21 , 22 , of which the front lap transport roller 21 is connected to a gear 23 which is driven by a motor 24 . The second lap transport roller 22 is connected to the first lap transport roller 21 via a belt drive, so that both lap transport rollers 21 , 22 are driven by the motor 24 and the gear 23 . A lap roll 1 lies on the lap transport roller 21, 22, from which the lap lap 4 is unwound by the rotary movement. The wadding 4 is wound onto a core 1a. The lap band 4 can be deflected on a roller 25 and transferred to a feed cylinder 26 of a tong unit 27 . On the roller 25, which is also driven here via the gear 23, a loaded about a lever 28 via a spring 29 pivotally mounted pressure roller 30 can be arranged. This embodiment with the roller, the spring-loaded lever 28 and the pressure roller is preferably only used in the automatic lap application process and does not have to be part of every combing machine. The tong unit 27 can be driven back and forth via a lever via a shaft 31 which is connected to the gear 23 . According to the example shown, the nipper unit 27 is in a forward position and transfers the combed-out tuft to a subsequent pair of detaching rollers 32. A circular comb 33 is rotatably mounted below the nipper unit 27, which combs out the tuft presented by the closed nipper via its comb segment. The circular comb 33 is also drive-connected to the gear 23 . A ratchet wheel, not shown, is fastened to the feed cylinder 26 and is rotated stepwise by the reciprocating movement of the nipper unit 27 by a pawl, also not shown, and thereby feeds the cotton sliver 4 to the pliers mouth of the pliers for combing out. During operation, the lap sliver 4 is continuously unrolled by the rotational movement of the lap 1 over the lap transport rollers 21, 22 and reaches the feed cylinder 26. The lap is then fed via the feed cylinder 26 to the jaws of the nippers unit 27 for combing out and then to the detaching rollers 32 delivered. The resulting fiber web is combined via pairs of take-off rollers 34, 35, 36 and a take-off table 37 by means of a sliver funnel 41 (cf. Fig. 2) to form a sliver F1-F8 and, together with the slivers also formed at the other combing heads, is fed to a drafting system 40 (cf 2). The web emerging from the drafting system is combined into a fiber sliver, the so-called comber sliver, and transferred to a sliver coiler for storage in a can.

The combed single-head tape then runs through the pairs of take-off rollers 34 - 36 and is delivered by them onto the take-off table 37 in the form of a tape or fleece. The short fibers, neps and impurities removed from the fiber material by the circular comb 33 and a top comb 38 are sucked as so-called noils through a guide shaft into a suction channel which is assigned to all the combing heads of the machine. According to Figure 2, the individual head slivers F1-F8 run from the various combing heads of the machine onto an outfeed table 39, usually side by side, to the common drafting unit 40. A sliver funnel 42 is arranged at the outlet of the drafting unit 40, which forms the web into a sliver F which is then placed in a can 10. The sliver funnel 42 has an integrated sensor with which the sliver mass or the sliver mass fluctuations are recorded. The sliver mass per unit of time is determined via the delivery speed of the combing machine K, ie the initial mass. FIG. 3 shows a first exemplary embodiment of the invention, in which a controller S processes the data for determining the noils. In an input device E, which can be designed as a keyboard or display, the winding fineness or incoming fiber mass m in ktex, the comb cycle number N in nips/min and the tension delay Dh2 _ΐ- 22/26 between the driven lap transport rollers 21, 22 and the Feed cylinder 26 entered. The tightening delay DP21-22/26 is therefore the speed difference between the lap transport rollers 21, 22 and the feed roller 26. Furthermore, the feed amount is entered manually into the input device E. The input mass of the fibers, i.e. the fiber mass m over the length of the lap belt 4, or converted via the speed of the lap transport rollers 21, 22, the fiber mass m for a certain period of time, is calculated in the controller S using this data. Tension draft differs from stretching in that the fiber sliver cross section is not equalized and two clamping points are not required. The contact of the lap lap 1 on the lap transport rollers 21, 22 and the associated friction in connection with the speed of the feed roller 26 are sufficiently precise for a defined tightening delay, so that the decreasing lap weight has no influence on this.

At the same time, a sensor signal is transmitted to the controller S via the sliver funnel 42, with which the initial mass of the combed fibers is determined over the length. Of course, the initial mass of the combed fibers per unit of time can also be determined by conversion via the delivery speed of the drafting system 40 .

The combing quantity is determined by the difference between the mathematically determined input mass and the sensor-determined output mass over the length of the sliver F or alternatively over a unit of time. The absolute or relative amount of noils is shown by means of an output device A, which can be designed as a display. According to the invention, the device and the method have a simpler structure than in the prior art. In particular, the measuring devices after each combing head 20 are omitted and only the total sliver mass (initial mass) of the sliver F at the sliver funnel is determined. The method according to the invention according to the exemplary embodiment in FIG. 3 involves a mathematical determination of the noil percentage, which is based, among other things, on the target values for the winding fineness. If there is a deviation from the target values for the winding count or fiber mass m in ktex, the tension distortion DP21-22/26 can be changed. Since the input mass is calculated and the output mass of the fibers is determined exactly by means of a sensor, the determination of the noils is sufficiently accurate so that the measuring device 42 only has to be calibrated once with little effort. Production data such as the number of comb cycles, tensioning delay, delivery speed and sliver count are routinely recorded on the comber and automatically used to calculate the noils. In the event of a process change, e.g. B. new submission fineness or feed amount, the manually entered data must be adjusted to the new values. The measuring system on the band funnel 42 for determining the initial mass can be used in parallel to determine the CV value, or an existing system for determining the CV values can be used to determine the initial mass. Determining the mass at the exit of the combing machine at the sliver funnel 42 or at the individual heads makes it possible to check for sliver breaks or web breaks. Thus, the currently used control z. B. omitted on fleece sheet. Recorded or already known data is used to determine and display the production size of the noil percentage during the ongoing process. The number of noils can be determined without additional mechanical effort, e.g. B. increased Fierstellkosten due to required sensors on the machine. Another advantage is that already recorded or known data can be used to determine and display the production size, noil percentage, during the ongoing process.

Possible influences from changes to the machine parameters and their effects on the percentage of noils are displayed directly or, if necessary, after adjusting the manually entered values, e.g. B. by the effect of the increased penetration depth at the top comb.

FIG. 4 shows a combing head 20, of which at least eight are mounted on a combing machine. For the sake of clarity, the exemplary embodiment is shown and described using only one combing head 20, with the details shown being installed on each of these combing heads except for the common drive units and the sliver coiler. The combing head 20 consists, among other things, of two lap transport rollers 21 , 22 , of which the front lap transport roller 21 is connected to a transmission 23 which is driven by a motor 24 . The second lap transport roller 22 is connected to the first lap transport roller 21 via a belt drive, so that both lap transport rollers unroll the lap lap 1 at the same speed. A lap lap 1 lies on the lap transport rollers 21, 22, from which the lap lap 4 is unwound by the rotary movement. In contrast to FIG. 1, the lap transport rollers 21, 22 can be arranged on a support 11, which is pivotably mounted by means of a joint 12 and rests with one side on a sensor 13, which can be designed as a load cell. The sensor 13 thus always determines the current weight of the lap roll 1, which continuously reduces over the time of the combing process. The sensor 13 thus transmits the current lap weight or the remaining weight of the lap roll 1 to the controller S, which is processed in the controller S via the lap length or alternatively over time, so that the input mass over the unwound length of the lap sliver 4 or per unit of time for each combing head 20 is processed. The embodiment with the sensors 13 for determining the current winding weight is necessary for the embodiments of FIGS. All other details of the combing process are identical to FIG. 1. The spring-loaded pressure roller 30 from FIG. 1 for automatic lap application is not shown here.

Fig. 5 is again identical to Figure 2, except for the mounting of the lap rolls 1, which cannot be seen here, which are arranged by means of the lap transport rollers 21, 22 on a support 11, which is pivotally mounted by means of a joint 12 and with one side on a sensor 13 rests, which can be designed as a load cell.

Flierzu belongs the second embodiment of the invention according to Figure 6, in which in a controller S the data for determining the noils are processed. This exemplary embodiment assumes the presence of the sensors _13i -13n for determining the winding weight. In an input device E, which can be designed as a keyboard or display, the winding gauge in ktex, the number of comb cycles in nips and the tightening delay D ^h ₂ i-22/26 between the driven lap transport rollers 21/22 and the feed cylinder 26 are entered. For each combing head 20, the data from the sensors _13i -13n are transmitted to the controller S, with which the current winding weight is determined. During the operation of the combing machine, the lap weight decreases, so that the input mass per running meter or per time interval can be calculated in the control via the unwound length of the lap 4 or via any time interval t. At the same time, a sensor signal is transmitted via the sliver funnel 42 to the controller S, with which the initial mass of the combed fibers is determined over the length of the sliver F or per unit of time. The amount of noils is determined by the difference between the input mass and the output mass over the length of the sliver F or per unit of time. The absolute or relative amount of noils is shown by means of an output device A, which can be designed as a display. According to the invention, the device and the method have a simpler structure than in the prior art. In particular, the measuring devices after each combing head 20 are omitted and only the total sliver mass (initial mass) of the sliver F at the sliver funnel 42 is determined. Using the data from sensors _13i -13n, fluctuations in sliver mass at each combing head 20 can be determined by means of the controller S at short time intervals, which can be directly compensated for by the tensioning delay between the driven lap transport rollers 21, 22 and the feed cylinder 26. Alternatively, the fluctuations in sliver mass and/or the display of the noils are used to determine errors such as a defective top comb or a worn round comb. The method according to the invention according to the exemplary embodiment in FIG winding gauge based. If there is a deviation from the target values for the winding count in ktex, the tensioning delay of the lap belt can be changed, or alternatively the calibration of the sensors _13i - 13n can be checked. Since the input mass and the output mass of the fibers are determined exactly, the calculation is very precise, so that the measuring devices _13i - 13n and 42 only have to be calibrated once with little effort, except for large deviations from the setpoint values of the winding count. If the tension distortion is not changed, fluctuations in the input mass of the fibers are not taken into account. Even then, the determination of the number of noils is still sufficiently accurate. Production data such as the number of comb cycles, tensioning delay, delivery speed and sliver count are routinely recorded on the comber and automatically used to calculate the noils. In the event of a process change, e.g. B. new serving size or amount of food, the manually entered data must be adjusted to the new values. The measuring system on the band funnel 42 for determining the initial mass can be used in parallel with the CV value determination or an already existing system for determining the CV values can be used for determining the initial mass. Determining the mass at the exit of the combing machine at the sliver funnel 42 or at the individual heads makes it possible to check for sliver breaks or web breaks. Thus, the currently used control z. B. omitted on fleece sheet. Recorded or known data is used to determine and display the production size of the noil percentage during the ongoing process. Influences from changes to the machine parameters and their effects on the display of the percentage of noils are displayed directly or, if necessary, after adjusting the manually entered values, e.g. B. the effect of the increased piercing depth on the top comb, or a defective top comb. The adjustment work on the comber is simplified, since the effects on the noil are displayed immediately (this applies to all essential combing head elements according to the amount of feed, e.g. top comb, circular comb, ecartement, soldering time, detaching roller movement. Furthermore, a good reference value for planning production , the waste quantity and to determine the machine parameters on the _{combing machine} , which has not previously been displayed on the combing machine For this purpose, the sensors _13i - 13n can be used to determine the current lap weight for each lap over time t, and the unwound length of each lap can be determined via the diameter and the speed of the lap transport roller 22. Both pieces of information can be used equally for quality control , where the amount of combs ge is the more common value over the length of the sliver F for spinning preparation. The incoming fiber mass per unwound winding length can thus be determined for each roll, with which fluctuations in the lap weight are recorded and the delay between the driven lap transport rollers 21, 22 and the feed cylinder 26 can be compensated.

A further exemplary embodiment of FIG. 7 provides for a fully automatic determination of the number of noils without manual input of values. In contrast to the exemplary embodiment in FIG. 6, the sensors _13i -13n for determining the lap weight can be arranged in groups, i.e. for four combing heads, for example, a support 11 with a joint 12 and a sensor 13. Two separate lap transport rollers 21, 22 are arranged for each lap lap 1 , both of which are powered. This

The exemplary embodiment does not provide an input device E for the winding fineness, the number of comb cycles and the tightening delay between the driven winding transport rollers 21/22 and the feed cylinder 26. For a group of combing heads 20, the data from the sensors _13i -13n are transmitted to the controller S, with which the current winding weight of the group is determined. During operation of the combing machine, the lap weight of the entire group is reduced, so that the input mass per time interval can be calculated in the control over any time interval t. At the same time, a sensor signal is transmitted via the sliver funnel 42 to the controller S, with which the initial mass of the combed fibers is determined over the length of the sliver F or per unit of time. The amount of noils is determined by the difference between the input mass and the output mass over the length of the sliver F or per unit of time. The absolute or relative amount of noils is shown by means of an output device A, which can be designed as a display. A further improvement can result if the sliver funnels 41 have measuring devices, so that after each combing head 20 the combed fiber sliver mass is determined. Using this recourse to the prior art, in combination with the group determination of the incoming sliver mass, deviations between the individual combing heads can be determined and compensated for via the tensioning delay of the driven lap transport rollers 21 , 22 and the feed cylinder 26 .

According to the invention, the device and the method of the exemplary embodiment in FIG. 7 have a simpler structure than according to the prior art. By collecting the data from the sensors _13i - 13n in groups, which is determined for an individual lap roll or for a group of two, four or eight lap rolls, the controller S can use the controller S at short time intervals to detect fluctuations in sliver mass on individual combing heads 20 or the group of Comb heads 20 are determined, which can be directly compensated for via the tension delay between the driven lap transport rollers 21/22 and the feed cylinder 26. The method according to the invention according to the exemplary embodiment in FIG Group detection of the incoming sliver mass for a group of combing heads. If there is a deviation from the target values for the winding count in ktex, the tensioning distortion of the wadding can be changed. Since the input mass and the output mass of the fibers are determined exactly, the calculation is very precise, so that the measuring devices _13i -13n, 41 and 42 only have to be calibrated once with little effort. If the tensioning distortion of the wadding is not changed, fluctuations in the input mass of the fibers are not taken into account. Even then, the determination of the number of noils is still sufficiently accurate. The production data such as number of comb cycles, tensioning delay of the lap sliver, delivery speed and sliver count sliver pull are routinely recorded on the comber, fed to the control and used automatically for the noil calculation. The measuring system on the band funnel 42 for determining the initial mass can be used in parallel to determine the CV value, or an existing system for determining the CV values can be used to determine the initial mass. Determining the mass at the exit of the combing machine at the sliver funnel 42 or at the individual heads makes it possible to check for sliver breaks or web breaks. Thus, the currently used control z. B. omitted on fleece sheet. Recorded or known data is used to determine and display the production size of the noil percentage during the ongoing process. Influences from changes to the machine parameters and their effects on the display of the percentage of noils are displayed directly or, if necessary, after adjusting the manually entered values, e.g. B. the effect of the increased piercing depth at the top comb. The adjustment work on the comber is simplified because the effects on the noil are displayed immediately. This applies to all essential combing head elements according to the feed amount, e.g. B. Top comb, circular comb, ecartement, soldering time, detaching roller movement. Furthermore, a good reference value for planning the production, the waste quantity and for defining the machine parameters on the comber is determined, which was previously not displayed on the comber.

The rotational speed P2 _ΐ , n22 of the lap transport rollers 21 , 22 can preferably be used to control the lap weight over the lap length. For this purpose, the sensors _13i -13n determine the current lap weight for the group of lap laps over time t, and the unwound length of each lap is determined via the diameter and the speed of the lap transport rollers 21, 22. The sliver mass fluctuation for each combing head can be determined by means of the measuring device on the sliver funnels 41, even if the incoming fiber mass is determined for the entire group of two, four or eight lap rolls. The difference in the measured values on the measuring device of the individual sliver funnels 41 in the group of combing heads enables the fluctuations in sliver mass to be determined. For each lap roll 1, the incoming fiber mass per unwound roll length can thus be determined are recorded, whereby fluctuations in the lap weight are compensated for via the delay between the driven lap transport rollers 21 , 22 and the feed cylinder 26 .

Based on the difference between the winding weight and the winding core, the exact point in time at which the lap roll 1 will run empty can be predicted. Systems currently in use, e.g. B. on the reflection of a light beam are no longer required.

The winding weight can be determined on the basis of the winding mass that arrives in a certain unit of time. For this purpose, the unwound length, e.g. B. on the diameter and the speed of the lap transport rollers 21, 22 to determine. A quality control of the winding machine with regard to the winding weight is thus possible.

The exact recording of the winding weight over the winding length enables the winding weight to be changed in a targeted manner on the upstream winding machine, e.g. B. to achieve a constant winding weight over the winding length via delay adjustment or to bring about deliberately desired changes in the winding weight.

According to these exemplary embodiments, the tightening delay Dh ₂ i-22/26 of the lap belt 4 between the driven lap transport rollers 21 , 22 and the feed cylinder 26 is set. This has the advantage of using the already driven winding rollers 21, 22 for the delay. Since not every combing machine has driven winding rollers, the tightening delay of the lap sliver can also be achieved by any other delay devices that are arranged in front of the feed cylinder 26 . The embodiment of FIG. 7 with the automatic determination of the combing percentage can be used both for individual combing heads or for groups of combing heads.

The reverse is also theoretically conceivable, namely the metrological recording of the input mass and a manually determined output mass on the comber.

Reference sign

1 cotton wrap

1a winding sleeve

4 cotton tape

10 pot

11 edition

12 joint

13l-13n sensor

20 comb heads

21, 22 lap transport roller

23 gears

24 engine

25 roll

26 food cylinder

27 tong unit

28 Flebel

29 spring

30 pressure roller

31 wave

32 detaching rollers

33 circular comb

34, 35, 36 take-off rollers

37 take-off table

38 top comb

39 outfeed table

40 drafting system

41 band funnel

42 tape funnel

A dispenser

E input device

F, F1 - F8 sliver

K comber

S control m tape mass

N number of comb games

DP21 -22/26 Tension delay P21, P22 Speed of lap transport roller

Claims

patent claims

1. Method for determining the amount of noils on a combing machine with several combing heads (20), wherein at each combing head (20) at least one lap sliver (4) is unwound from a lap roll (1) and fed to a gripper unit (27) by means of a feed cylinder (26). the noils are combed out of the lap sliver (4) and sucked off by means of top and round combs (33, 38), and the resulting fibrous web is formed into a sliver (F1 - Fn) by means of a sliver funnel (41), which is connected to the others Slivers of the other combing heads is drawn into a single sliver (F), the sliver mass of all combed slivers being determined before the can deposit, characterized in that the sliver mass (m) of all lap rolls entering the combing machine, the number the comb games (N), a tightening delay of the cotton sliver (4), and the feed amount are entered manually and converted in a controller (S) to a sliver mass to be combed w ird, wherein the controller (S) deducts the outgoing sliver mass determined by the sensor from this sliver mass to be combed and displays the quantity of combed noils by means of an output device (A).

2. Method for determining the amount of noils on a combing machine with several combing heads (20), with at least one lap sliver (4) being unwound from a lap roll (1) on each combing head (20) and fed to a gripper unit (27) by means of a feed cylinder (26). the noils are combed out of the lap sliver (4) and sucked off by means of top and round combs (33, 38), and the resulting fibrous web is formed into a sliver (F1 - Fn) by means of a sliver funnel (41), which is connected to the others slivers of the other combing heads is stretched into a single sliver (F), the weight of the lap laps at the combing head and the sliver mass of all combed slivers being determined before the can deposit, characterized in that within a controller (S) the weight of the lap laps or the Weight change over the length of the unwound wadding strip (4) or over a certain time is converted into an incoming strip mass (m) and from this strip mass to be combed sse deducts the outgoing sliver mass determined by the sensor and displays the quantity of combed noils by means of an output device (A).

3. The method according to claim 2, characterized in that the number of comb games (N) and a tightening delay of the lap belt (4) are entered manually by means of an input device (E).

4. The method according to claim 2, characterized in that the weight of the lap roll (1) is determined at each combing head (20).

5. The method according to claim 2, characterized in that the combined weight of the lap rolls (1) of a group of combing heads is determined.

6. The method according to any one of the preceding claims 1 or 2, characterized in that fluctuations in the fiber mass to be combed at each combing head (20) are compensated for by changing the tensioning delay of the lap sliver (4).

7. The method according to any one of the preceding claims, characterized in that a strip breakage can be detected by determining the outgoing strip mass.

8. The method according to any one of the preceding claims 1, characterized in that the amount of noils combed out can be changed by setting machine parameters such as the insertion depth of the top comb, changing the eccentricity and/or changing the number of comb games.

9. The method according to claim 5, characterized in that the combed sliver mass is determined after each combing head.

10. The method according to any one of the preceding claims, characterized in that the tightening delay (D ^h ₂ i-22 _/ 26) of the lap belt (4) between driven lap transport rollers (21, 22) and the feed cylinder (26) is adjustable.

11. A combing machine with several combing heads (20), wherein at each combing head (20) at least one lap sliver (4) is unwound from a lap roll (1) and fed to a gripper unit (27) by means of a roller (25) and a feed cylinder (26). , the noils are combed out of the lap sliver (4) by means of a top and round comb (33, 38) and sucked off, and the resulting fiber web is formed into a sliver (F1 - Fn) by means of a sliver funnel (41), which is connected to the others

slivers of the other combing heads is stretched into a single sliver (F), the weight of the lap laps on the combing head and the sliver mass of all combed slivers being determined by sensors before the can coiler, characterized in that by means of an input device (E) the incoming into the combing machine tape mass (m) of all batting rolls, the number of nips (N), a

Delayed tensioning of the lap sliver (4) and the feed amount are entered manually, and a controller (S) is designed to convert the entered data into a sliver mass to be combed, the controller (S) deriving from this sliver mass to be combed the output determined by the sensor tape mass deducts and displays the amount of noils combed out by means of an output device (A).

12. A combing machine with several combing heads (20), wherein at each combing head (20) at least one lap sliver (4) is unwound from a lap roll (1) and fed to a gripper unit (27) by means of a roller (25) and a feed cylinder (26). , the noils are combed out of the batting sliver (4) by means of top and round combs (33, 38) and sucked off, and the resulting fibrous web is formed into a sliver (F1 - Fn) by means of a sliver funnel (41), which is connected to the other slivers of the other combing heads is drawn into a single sliver (F), the weight of the lap laps on the combing head and the sliver mass of all combed slivers being determined by sensors before the can deposit, characterized in that a controller (S) is designed to process the sensor data by converting the weight of the lap roll or the change in weight over the unwound length of the lap sliver (4) or over a specific time into an incoming sliver mass (m) and v on this to be combed

Sliver mass deducts the outgoing sliver mass determined by the sensor and displays the quantity of combed noils by means of an output device (A).

13. A combing machine according to claim 12, characterized in that each combing head (20) has a sensor (13) for determining the weight of the lap roll (1).

14. A combing machine according to claim 12, characterized in that a group of

Comb heads has a sensor (13) for determining the combined weight of the lap rolls.

15. A combing machine according to claim 11 or 12, characterized in that each combing head has a device for changing the tensioning delay of the lap sliver (4).

16. The combing machine as claimed in claim 15, characterized in that the combing machine has driven lap transport rollers (21, 22), with a change in the speed of the driven lap transport rollers (21, 22) and/or the speed of the feed roller (26) causing a tensioning delay (D ^h ₂ i-22 _/ 26) is adjustable.

17. A combing machine according to any one of the preceding claims 11 to 16, characterized in that the sensor on the sliver funnel (42) is designed to detect a sliver break.

18. A combing machine according to claim 14, characterized in that a sensor for determining the sliver mass is arranged on the sliver funnel (41) after each combing head (20).

19. A combing machine according to claim 11 or 12, characterized in that the controller (S) is designed by means of the diameter and the speed of the

Winding transport rollers (21, 22) to detect the winding weight over the winding length.