RU2098339C1 - Thread feeder for textile machines - Google Patents

Abstract

FIELD: textile industry. SUBSTANCE: thread feeder has brake for at least one thread removed from bobbin by drive electric motor. Thread is wound in subsequent coils onto feed drum. At least one thread running off the drum is passed through thread tension indicator whose mechanical deflection is calculated by electronic devices and is converter into signals to control electric motor drive and thread feeder. Feed drum is made integral with rotor of drive electric motor to accumulate required amount of thread and is provided with X-positioned steel wires to form wire net over perimeter. Thanks to it one or two threads can be removed from feed drum. EFFECT: enlarged operating capabilities. 18 cl, 7 dwg

Description

 The invention relates to a yarn feeder used as a feeder for textile machines.

 Thread-feeding devices are also known, also called storage feed reels as a filament feeder for textile machines, containing a storage drum that is attached to the end of an electric motor shaft and on the circumference of which many windings of thread are laid that need to be transferred to the machine (1). The speed of rotation of the storage drum is transmitted directly to the electric motor of the storage drum through a control electronic circuit by means of a corresponding pulse drive on a round knitting machine. Thanks to this, auto-synchronization between the machine and the thread feeding device is achieved. Next, the sensors that respond to the thread re-adjust the desired speed setting.

 In addition, it is known thread-feeding device, the feeding storage drum of which is also mounted on the end of the motor shaft (2). However, in this device, the signal is supplied to the electric motor through the lever of the thread sensor, which is held in a variable position by an electromagnetic method. Adjustable return force on the lever corresponds to a variable set value of thread tension.

 When directly turning on the circular knitting machine, a certain amount of thread is urgently required, respectively, of a given parameter. Necessary for this known electric motors with sufficient torque to start winding and, accordingly, the necessary acceleration time, have structural dimensions that cannot be installed in the dimensions of the housings currently in use. For this reason, the known devices have a sensor lever, which creates a variable reserve of thread between the feed drum and the thread consumer. When this reserve is consumed, the electric motor can be set to the desired number of revolutions, which will correspond to the desired supply quantity. This reserve of the thread is created by repeatedly turning the direction of the thread, for example, using the eyes. However, this causes friction and pile formation losses. Moreover, rubber-elastic threads in this way are difficult to regulate, or in all cases you have to work only at very slow speeds.

 Known thread-feeding devices for the purpose of normal winding on the feed drum have an upstream, rigidly adjusted or alternating thread brake. To do this, the thread is either passed through the eyelet, which is weighted, for example, by means of a ball, or it is pulled through a disc brake. But here, depending on the material used, hairy formations arise. The strands of thread on the feed drum with high braking forces will lie rigidly and pulled, and most types of threads will be stretched. The thread will relax at the measuring point, for example, on the sensor lever, and the lever itself may vibrate. Therefore, the lever must be brought to a calm state mechanically.

 All known devices thus have several weak points, which should be considered as a general unsatisfactory solution with too high technical costs.

 The objective of the invention is to create a thread feeding device, in which individual nodes of the structure are most precisely coordinated (joined) with each other with the formation of an optimal single system. A further object of the invention is to improve and optimize individual components of the device for efficient use.

 This task yarn feeder according to the main idea of the invention is solved by the distinguishing features of claim 1. The subparagraphs of the claims indicate the preferred and appropriate, as well as partially independent embodiments of the invention as private technical solutions.

 The yarn feed device according to the invention has the advantage with respect to known devices that all structural elements of the device are matched in cooperation with each other. In order to ensure direct replacement of the known devices with a belt drive and their desired dimensions, a completely new direct current electric motor was developed, which is electronically driven, which has a number of advantages compared with the known stepper motors. These advantages lie in the very simple design of the electric motor with its very small moving mass, at least with the same or better acceleration characteristic. The EC motor, by the nature of its design, provides operation with a non-stop force in a de-energized state, so that simple mechanical threading of the thread becomes possible. Due to the use of a lightweight rotor or armature, which is the carrier of an electromagnet (permanent magnets), it is possible to obtain very compact dimensions with a very small axial length. At the same time, the operation of the electric motor creates little noise, high efficiency and slight heating. The possible arrangement of an appropriate platinum with electronics near the electric motor allows a very compact design of the entire device. High efficiency provides high-quality permanent magnets in the rotor, which interact with the corresponding number of groups of coils on the stator.

 A significant advantage of the invention is the combination of an electric motor with a storage feed drum connected at the same time. The anchor or rotor of the DC motor serves as a support for the feed drum, and despite the mass of high-power electromagnets, a system has been created that is extremely light in weight and thus easily accelerated. For this purpose, the system is formed of a lightweight plastic disk (platinum) as an electromagnetic carrier, and anchors on which are laid x-shaped steel wires connected to the outer ring. These x-shaped wires along the perimeter of the feed drum form a ramp (slope) for the thread, and two threads can be fed simultaneously.

 Another advantage of the invention is to control the tension of the thread after the storage feed drum, which is carried out by a coil spring of tubular shape in cross section or made as a cone of rotation. The deviation of the spiral spring is directly related to the pulling force of the thread and thus its quantity consumed.

 By electronically processing the values of the deflection of the coil spring, direct, immediate control of the drive motor of the storage feed drum takes place.

 Of particular advantage is the thread brake, which is provided in front of the feed drum, which operates with minimal bearing friction and is installed and / or adjustable by an external magnetic field. In this way, the approach of the thread to the feed drum can be adjusted and adapted.

 The filament brake, feed drum and coil spring are so coordinated with each other according to the adjusting technology that the optimum thread feeding for the textile machine is guaranteed.

 In FIG. 1 shows a yarn feeder, side view; in FIG. 2 same front view; in FIG. 3 the same, with a longitudinal section of a DC motor; in FIG. 4 a more detailed image of the supply drum; in FIG. 5 spiral spring tension control thread; in FIG. 6 thread brake in cross section; in FIG. 7 is a schematic illustration of a probe for a broken thread.

 The thread feeding device 1, shown in FIGS. 1-3, consists of a housing 2 for installing and securing a drive motor 3 and a platinum 4 for control electronics. The drive motor 3 forms a constructive unity with the storage feed drum 5, shown in more detail in FIG. 4, a, b.

 The thread feeding device 1 has a thread brake 6, a thread breakage probe 7 located in front of the feed drum 5, and a thread tension indicator 8, which is connected to control the thread tension after the drum 5. A more detailed description of this system is given in figures 5, a, b.

 FIG. 3 represents in detail the driving unit 9 of the thread feeding device 1, consisting of a drive motor 3 and a supply storage drum 5.

 The electric motor 3 is made in a four-pole version, connected to the electronic device as a DC motor.

Due to the design of the disk rotor, it has a small axial length. The DC motor 3 consists of a rotor or armature 10 in the form of a plastic disk, which serves as an electromagnetic carrier. Four circular or otherwise molded permanent magnets 12 are mounted in the plastic disk 11. The stator 13 of the DC motor consists of two groups of coils 14, 15 with back-closure plates 16, 17 mounted on the hollow axis 18. On the axis 18 with two bearings 19, in order to balance the alternating tilting moment caused by the magnetic field, the rotor 10 is placed. The hollow shaft 18 with one longitudinal hole 20, as well as two transverse drilled holes 21, 22 at its corresponding end, serves to install the wires of the circuit connection 23 between the group of coils 14 and the control plate 4. The group of coils 15, through the corresponding wire 23 ^{1 of the} circuit connection, is connected to the inclusion plate 4. This hollow shaft 18 has one circuit connection wire on which the light break detector operates.

 The groups of coils 14, 15 are completely identical in design and therefore they can be manufactured using the same tool.

 The hollow axis 18 penetrates the platinum 4 for control electronics and is secured with a nut 24 on the back of the housing.

The rotor 10, like the plastic disk 11, is made in such a way that it also serves as part of the design of the storage feed drum 5. For this, the outer rim 25 of the plastic disk 11 has one envelope protrusion 26 with holes 27 into which individual wires 28, 28 are embedded ¹ cross of the filament, which, enveloping, form a wire mesh 29 (see Fig. 4, a, b). The wire mesh 29 on the side opposite to the plastic disk 11 is bounded by an external plastic ring 30, also having holes for securing the individual wires 28, 28 ¹ .

On the outer diameter or on the surface thus formed, the holder of the plastic ring 30 or disk 11 contains from 5 to 8 crosses of the feed in an x-shaped pattern, consisting of polished steel wires 28, 28 ¹ , which together form a wire mesh 29 located on the outer surface casing of the feed drum 5. The angle "α" in the axial direction of the drive motor between the two respective wires 28, 28 ¹ is from about 60 to 110 ^o (see Fig. 4, a).

 The DC motor 3, electronically controlled, is de-energized without stopping force so that simple manual winding of the threads is possible. Due to the low weight design of all rotating parts of the rotor 10 and the supply drum 5, as well as due to the use of high-quality permanent magnets 12, they get an extremely short acceleration time of the electric motor. In this case, the electric motor is controlled by the reaction force to adjust the thread tension. Due to the high efficiency of the DC motor, slight heating is generated. Thus, the platinum 4 electronics can be located in close proximity to the motor, due to which they get a very compact design of the entire device.

 As can be seen from FIG. 1 and 3, the supply drum 5 on its front side is equipped with an additional one flashing light detector 32 for indicating a broken thread. Shown in FIG. 2, the front side of the device, as well as the corresponding side view in FIG. 1, further shows the supply of two threads 33, 34 to each feed eye 35, 36, the supply of dual threads to the brake 6. This thread brake, shown in more detail in FIG. 6, consists of two sealed bearings 37, 38 located adjacent to each other in the bearing housing 74, at least one turn of the corresponding thread 33, 34 is superimposed on the outer side surface thereof. This preserves the input direction of the thread. Between the bearings 37, 38 in the bearing housing there is one permanent magnet 39 with axial magnetization in the form of two sectors, i.e. with the upper north and lower south poles. With each rotation of the corresponding bearing, its ball is once attracted, for example, to the north pole, and in the next sector, the south pole is repelled, due to which the braking effect occurs due to friction of the bearing.

 Between the brake 6 and the spool of thread there are certain feed resistances. It was found that the outer ring of the corresponding ball bearing 37, 38 does not rotate when the leading resistance in the direction of the coil is low. A loop formed around the bearing slides to the outer diameter or to the side surface of the bearing and produces only a slight braking effect. If the feed resistances between the spool and the drum increase due to sporadic resistances, such as knots or pile accumulation, the thread loop will be tightened around the outer ring of the bearing, which will cause the outer ring of the corresponding bearing to be gripped 37, 38. As a result of these variable effects, almost horizontal graphical characteristic of braking, i.e. extremely uniform filament feed.

 If the permanent magnet 39 is replaced by a conductive electromagnetic coil, then the braking force can be adjusted over a wide range. The thread brake 6 can be equipped with one ball bearing for feeding one thread or one double bearing for two threads. Since two bearings are provided, both give a braking effect, independent of each other.

 Behind the brake 6, a probe 7 of a thread break is connected (see Fig. 2.7).

The support 40 mounted in the housing 2 serves as a support for the lever 41. At the upper end of the lever 41, a pin 42 is located vertically to the lever 41, which is held in position or position by means of passing threads 33, 34. When the thread breaks, the lever 41 due to gravity falls to the position of the probe 7 ¹ breakage of the thread, shaded in FIG. 2. At the lower end of the lever 41, the shaft 43 passes through the bearing 40. At the lower end of the shaft 43 there is a permanent magnet 44, which is installed so that by means of the deflecting movement of the shaft of the lever 43 the by-relay is switched on or off. At the same time as the circular knitting machine is turned off, the on-board relay 45 controls the operation of the light detector for the breakage of the thread 32. The lever 41 with the pin 42 transfers only a slight friction effect to the thread 33, 34. To the same extent or alternatively, it can be installed between the feed drum 5 and the thread tension indicator 8, in order to control the break there in a similar way.

 With a horizontal arrangement of the device, the deviation of the lever 7 when the thread breaks can be done by means of an additional spring. The device can thus be operated in any position.

 The device with its front side of the service 77 of the circular knitting machine is directed mainly radially outward to provide affordable frontal service.

 The thread 33, 34, passed through the brake 6 and the open probe 7, is fed to the feed drum 5 in accordance with the image in FIG. 1, 2 and 7. To this end, the drum 5 and the rotor 10 of the drive motor 3 form a structural unity, and extremely light materials are used, so that very little mass is subject to acceleration. The motor acceleration time is so short that the filaments can be fed at a speed of up to about 10 m / s directly into a running machine.

 The cyclic, brushless electronic control of the rotor 10 provides extremely low power consumption, which is three times lower than the amount of electricity consumed by known devices. Electricity consumption during overloads is automatically kept at the adjusted maximum value, so that even during a long stop under load, no damage to the rotor, armature or winding can occur.

Polished steel wires 28, 28 of ¹ x-shape, used to form a wire mesh 29 provided on the side surface of the feed drum 5, provide automatic filament feed on this drum.

With this construction according to the invention there is no need for special running bevels of known devices, as this occurs by the x-shaped arrangement of the wires 28, 28 ¹ themselves.

No starting point for the thread on the drum 5 is required. Thread 33, 34, as shown in detail in FIG. 1 in conjunction with FIG. 4a, can be fed to the left half 46 and to the right 47 of the width "b" of the wire mesh 29. If the total width "b" of the wire mesh 29 is divided into six parts (2x3 / 3), then each thread can be fed to both without problems external sections 48, 49, having a width a ≈ b / 3. Therefore, the point of incidence of the corresponding thread 33, 34 on the feed drum 5 can be freely selected depending on the desired length of the roll, since the outer section of the incidence 48, 49 allows many turns. At the same time, it is possible to feed and feed two threads for two different knitting systems with the same thread consumption. Due to the x-shaped arrangement, respectively, of two wires 28, 28 ^{1 of the} wire mesh 29 directed towards each other, each wire extends mainly on an x-bevel to the mid-crossing point 50 of the respective wires (center line 51). Therefore, the run-in of the thread is not at all dangerous, since individual turns lying respectively next to each other are strung in a row.

Therefore, from the center line 51 connecting the intersection points 50 with each other, left and right wound threads are joined. In FIG. 5, for example, a feeding drum 5 is shown, in which four turns of thread 52 lying adjacent to each other are wound on the lower half of the drum 5. Each individual or both oncoming runs mainly from the midline 51, as shown in FIG. 4, a. In this case, both outgoing threads lie, touching, adjacent to each other at the x-shaped intersection point. Since in this place the diameter of the feed drum 5 has the same value for both threads, the length of both threads is identical. On the middle line 51 for separating both outgoing threads, a round separation plate 75 can be installed. It is not necessary to fix the plate, since there are transverse holes 76 through which the intersection point 50 of the wires 28, 28 ¹ passes.

 As follows from FIG. 1,2 or 5a, a thread tension indicator 8 is connected to the feed drum 5, which serves to control the tension. Since both threads 33, 34, removed from the drum 5, are mainly removed from the same outer diameter of the drum 5, namely from the middle line 51 (x-shaped intersection point 50), in principle, it is sufficient that only one thread 33 is controlled indicator 8 tension, while the other thread 34 from the drum 5 is carried out directly through the eye 53 (see Fig. 2).

 The double threading of the thread-feeding device with threads 33, 34 in comparison with traditional devices working with only one thread is of great importance from an economic point of view.

 If during the knitting process the tension of the thread automatically or manually changes, then the uncontrolled thread also changes its tension.

By a special arrangement of the x-shaped wires 28, 28 ^1, for some types of filament, in this case, the brake 6 can be dispensed with, since most often the resistance of the thread itself is sufficient to carry out its braked winding on the feed drum 5. The resistance of the thread is formed, for example, by the process of winding it from the spool and the associated redirection of movement.

 Uncoated rubber threads can also be processed in the device. In this case, the thread can be passed by the brake 6 without touching it. A thin lacquered copper wire can be easily wound onto the feeding drum 5 and removed with the desired tension, and the lacquer insulation is not damaged.

 Depicted in FIGS. 1,2 and 5, a, b, the control of the thread tension by means of indicator 8 is carried out mainly by means of a spiral, pipe-wound spring 54, which is mounted on the rotary head 55. The head 55 has a shaft 56, wound in the bearing 57 inward housings 2. At the lower end of the shaft 56, a permanent magnet 58 is centrally or eccentrically fixed so that it lies on the north-south dividing line on the middle axis 59 of the device (see Figs. 2 and 5, b). The iron yoke 60 of the Hall indicator 61 on the opposite side holds the magnet 58 in the middle position "M", as shown in FIG. 5. The dividing line 62 between the north-south poles of the permanent magnet 58 is located on the middle axis 59. The Hall indicator 61 is positioned so that when the slightest deviation of the angle b from the middle position "M" activates the motor control. Just a slight increase in the tension of the thread 33 causes the coil spring 54 to be deflected, located on the midline 59 in the direction of the arrow 63 in FIG. 2, 5, a, b.

This deviation of the angle b controls the number of revolutions between the zero value and the total number, and the angular deviation is so small and short-lived that the optical movement is difficult to distinguish. Due to the special design of the electric motor, a very short acceleration time can be obtained. Therefore, a special thread storage device is no longer required. The control permutation of the thread tension can be done manually on the potentiometer 64 or on a computer controlled via line 65 of the processor. By adjusting the offset zero voltage on the Hall display, the desired north-south transition position of the permanent magnet 58 can be shifted, so that the thread tension can be adjusted using V _reb or electronic control.

 The design of the indicator 8 of the thread tension with a coil spring 54, wound in the form of a pipe, has the advantage that absorbed vibrations that can occur due to the polygonal substrate for the thread around the perimeter of the feed drum 5, due to which a quiet thread descent is achieved.

 A coil spring 54 of a tubular shape with a top exit 66 of the same shape for tangential winding of the thread 33 also represents a damper link in the placement of the thread tension indicator 8.

 Reference 66 in FIG. 2 indicates the optical indicator of the set value, position 67 to the optical operating indicator of the device, position 68 to the device on and off device.

 In FIG. 1 or 3, standard pins 69, 70 are shown, which, together with the connection to the housing 71, provide the necessary power. The connection 69, 71 serves to provide the device with the necessary known voltage of 24 V. The pin 70 serves as a conductor for stopping the machine when the thread breaks.

 A special embodiment of the thread-feeding device allows direct replacement of known belt driven devices. At the same time, the knitting machine undergoes a significant simplification. The devices can be operated in any position, since the probe 7 breaks the thread, not supported by its own weight, but can fall through the spring when the thread breaks. The thread can be started from the eyelet 35, 36 without changing direction through the brake 6 to the indicator 8 of the thread tension. At the same time, the tubular shape of the coil spring 54 allows a smooth rotation of the thread inside the spring, as well as smooth wiring inside the spring to its lower outlet 72. As a result, a barely emerging pile formation along the entire length of the thread is obtained.

 All devices managed to be reduced by half compared with belt-driven devices. Thanks to the brushless drive motor 3, a service life is automatically achieved, which depends on the service life of the ball bearings used. Devices thus do not require maintenance.

 No additional light bulbs are required to indicate a broken thread. The durable flashing system based on the light detector 32 breakage of the thread allows you to have a service life of 5 to 10 years.

 If a traditional knitting machine required two or more different threads, then the problem was solved by a large number of drive belts on several planes. The mechanical costs were correspondingly high.

 The proposed devices automatically adapt to the desired number of threads, and at the same time, the working tension of the thread is adjusted. In this case, the drive motor is designed so that it does not have locking moments. Therefore, the threads can be pulled through the feed drum 5 with almost no resistance.

 The invention is not limited to the described and illustrated embodiment. To a large extent, it covers all special subsequent developments and modifications within the scope of the invention.

Claims (18)

 1. A thread feeding device for textile machines, comprising a brake for at least one thread being wound from a bobbin, a storage drum, the casing of which is mounted for rotation from an electric motor, and its working surface for receiving and storing the thread in the form of successive turns is made in the form of a frame made of steel wires, and a thread tension indicator installed after the storage drum, connected to an electric motor control system to regulate the drum drive with mechanical deflection ikator, characterized in that the housing of the storage drum is made in one piece with the rotor of the electric motor, and the steel wires of the frame are X-shaped with the formation of a mesh around the perimeter of the drum.  2. The device according to p. 1, characterized in that the electric motor is made in the form of a brushless electronic commutated DC motor, the anchor or rotor of which is made in one with the storage drum, the rotor is equipped with high-power permanent magnets, and the stator consists of two opposite groups of coils with reverse circuit plates.  3. The device according to p. 1 or 2, characterized in that the rotor is made in the form of a plastic disk, which serves as a magnetic carrier for the installation of four permanent magnets.  4. The device according to p. 3, characterized in that the electric motor in a de-energized state is configured to control the tension of the thread.  5. The device according to one of paragraphs. 2 to 4, characterized in that the rotor shaft is made in the form of a hollow axis with transverse holes at its ends to establish wires for the circuit connection to the coils and the light indicator of the breakage of the thread.  6. The device according to p. 1, characterized in that the storage drum to provide the machine with the required number of threads has an X-shaped wire mesh on the side located on the perimeter of the rotor of the electric motor.  7. The device according to paragraphs. 1 to 6, characterized in that the plastic disk of the rotor with the drum is made with the formation of one node of light material, and the plastic disk is formed by an internal disk, which on its outer perimeter has a crown with connecting holes for wires, and X-shaped wire mesh connected to an external plastic ring.  8. The device according to p. 7, characterized in that the wire mesh is formed by 4 to 8 crosses that are tangentially installed in the closed side surface between the outer edge of the plastic disk and the outer plastic ring.  9. The device according to claim 8, characterized in that the tension indicator is made in the form of a cylindrical or conical spiral spring through which the thread is passed.  10. The device according to p. 9 or 10, characterized in that the coil spring in its upper section is made expanded in the form of a funnel for receiving the thread, and in the lower section it is connected to a head mounted on a rotation axis parallel to the axis of the electric motor, with the possibility of rotation from traction force of the thread.  11. The device according to p. 10, characterized in that the axis of the coil spring bearing is rotatably mounted and connected to a motor speed control unit and a permanent magnet connected to the Hall voltage changing means.  12. The device according to p. 1, characterized in that the brake is made with two ball bearings for wiring two strands along their outer rings, while the ball bearings are configured to control their friction resistance.  13. The device according to p. 12, characterized in that to ensure friction resistance, an electromagnet is installed between the ball bearings, the north and south poles of which are parallel to the hinges of each ball bearing.  14. The device according to p. 12, characterized in that in order to provide adjustment of the friction resistance of the ball bearing, a coil controlled by an electromagnet is provided.  15. The device according to one or more of paragraphs. 1 to 14, characterized in that it provides for the shuttle of the thread breakage as a rocker lever to stop the drive when the thread breaks.  16. The device according to p. 15, characterized in that the rocker arm support has a rotating shaft and a permanent magnet connected to it, controlling when the current relay is deflected, to activate the light indicator for thread breakage and to turn off the machine.  17. The device according to claim 1 or 6, characterized in that a disconnecting washer having transverse holes for laying the wires is inserted at the intersection points of the wire frame.  18. The device according to p. 1, characterized in that its service side relative to the location of the textile machine is directed radially outward.

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