RU2592177C2 - Device to control tape base and circular weaving machine - Google Patents

Abstract

FIELD: textile.

SUBSTANCE: warp band stop motion (1) for looms, in particular circular looms, comprises a sensor piece that has a passage for a warp band. Sensor piece can be moved back and forth between a preloaded rest position and a working position, into which sensor piece can be moved by a tensile stress of warp band passing through sensor piece. Rest position detector detects presence of sensor piece in rest position or approach of sensor piece toward rest position. If rest position of sensor piece or approach of sensor piece toward rest position is detected, detector emits a rest position signal.

EFFECT: warp band clamping device is provided, between which device and sensor piece warp band can be clamped when sensor piece moves into rest position thereof.

19 cl, 10 dwg

Description

The invention relates to a base ribbon control device for weaving machines, in particular round weaving machines, having a sensor element, which has a passage for the base ribbon, wherein the sensor element can reciprocate between the initial position in which it has a prestress, and the working position to which it can move due to the tension of the base ribbon passing through the passage, and having a starting position detector that detects the presence of the sensor element ententa in the initial position or the proximity of the sensor element to the initial position, and when the initial position of the sensor element is detected or close to the initial position, it sends a signal to the initial position.

The invention also relates to a round weaving machine, in which a plurality of warp ribbons can be connected to a round reed having a main drive and a control device, while the round weaving machine is equipped with warp ribbon control devices.

Round looms have long been known. They usually have a round reed, to which from the frame called “creel” or so-called navoi many ribbons of the base are fed. These ribbons of the warp in a circular reed by means of warp ribbons located around the central axis of the warp, which are most often made in the form of groups of belts with eyelets that can reciprocate by means of the upper and lower rollers, counter-upward and downward alternating motion is communicated in pairs due to which, between the groups of ribbons of the warp, a pharynx is formed in which one or more coils with duck ribbons circulate on the weaving shuttles around the central axis and at the same time ayut ribbon duck between the two groups of ribbons base thereby forming a tubular fabric, which is pulled out of the circular loom is further processed or wound up in bales.

Round looms of this kind are known, for example, from document EP 0 786 026 B1.

A creel, always equipped with a plurality (usually hundreds) of warp ribbon coils, or coils, which always consist of a rotating axis and a plurality of warp ribbon warps independently wound on this axis, are usually located on the sides of a circular weaving machine on two or more sides. The warp ribbons of each spool are individually fed to a round reel of a round weaving machine. Each time the base ribbon coil or, respectively, the base ribbon winding is used up, i.e. the warp ribbon on it has reached its end, the corresponding empty spool with warp ribbon should be replaced with a full spool (for example, the whole one) and new / new warp ribbons should be fed into a round weaving machine. This dressing process can be simpler if the end of the previous warp ribbon has not yet been pulled into a round weaving machine. Then you can, in particular, simply knot the end of the previous warp ribbon with the beginning of a new warp ribbon so that you do not need to refill a new warp ribbon into a round weaving machine. To do this, however, it is necessary to be able to timely recognize the consumption of the base ribbon coil, which is sometimes difficult with several hundreds of ribbon base coils.

For this purpose, base ribbon control devices have been developed in the past that can recognize the consumption of the base ribbon coil and give a warning signal. Such a control device is known, for example, from document DE 562975.

However, it turned out that merely indicating the end of the warp ribbon often cannot prevent damage to the round weaving machine, because due to the inevitable loss of tension that occurs when the end of the warp ribbon comes off the spool, the corresponding warp ribbon moves indefinitely in the round weaving machine. loops that are rewound with other ribbons of the warp or wound around the moving parts of a round weaving machine and interfere with their proper movement. The consequence of such endlessly “hanging” ends of the warp ribbon in a round weaving machine can be fatal and lead to significant destruction of the round weaving machine. Regardless of this, due to the suddenly weakening tension when the base ribbon coil is used up, the end of the base ribbon, like a rubber band, is thrown forward, because of which it most often falls into a position in which it can no longer be grasped to tie the spare ribbon of the base.

The objective of the present invention is to provide a solution to the above problems of the prior art.

The present invention solves this problem in a first aspect by improving the aforementioned base ribbon control device, wherein a base ribbon clamping device is provided between which the base ribbon can be gripped when the sensor element is moved to its original position. Due to this measure, not only is the end reaching achieved and at the same time the warp of the warp coming off its spool, but also the end region of the warp ribbon is held before it can be pulled into a round weaving machine. In this way, the possibility of causing the base tape to come down in a round weaving machine is reliably prevented. In addition, the end of the warp ribbon is available in a well-defined position for attaching a spare warp ribbon.

The initial tension of the sensor element in its initial position may, for example, be due to gravity and / or spring force.

The present invention solves the aforementioned problem in the second aspect by providing a round weaving machine on which a plurality of warp ribbons can be connected to a round reed that has a main drive and a control device, while the round weaving machine is equipped with the inventive warp ribbon control devices, the initial position signals of which can be transmitted to the control device, while the control device stops the main drive when the initial position signal occurs . Thanks to the stop of the main drive, it is possible to insert a new coil of the base ribbon and to connect the beginning of a new ribbon of the base with the end of the detected come down ribbon of the base, while it is clamped by the inventive ribbon control device.

Other advantages and features of embodiments of the inventive base ribbon control device are explained below.

In one of the improvements of the base ribbon control device, the passage for the base ribbon in the sensor element is made across the direction of its reciprocating movement between the initial position and the working position. This creates a short and, therefore, with low friction loss path of the base ribbon through the sensor element. In addition, the occurrence of deflecting forces acting on the sensor element obliquely to the bias direction is prevented. Finally, in this embodiment, the changes in the ribbon tension of the warp and the associated more or less severe sag lead to significant displacements of the sensor element, which, of course, can be detected more easily than small mixes.

Preferably, the passage for the warp ribbon in the sensor element is made in the form of an open side groove, thereby achieving great time savings when attaching the warp ribbon when preparing a round weaving machine for use.

In order to provide predetermined clamping forces between the clamping device and the sensor element, it is preferable if the sensor element is rotationally supported.

High clamping forces acting on the base ribbon can be achieved when the clamp device in the inventive base ribbon control device is equipped with a friction surface made in the form of a friction surface, while preferably the friction surface is in the form of a friction coating, such as, for example, a rubber lining or surface roughness, or notches made.

In order to ensure that the base ribbon is clamped between the clamping device and the sensor element, in one embodiment of the invention, a clamping surface and / or a surface of the sensor element facing the clamping surface are provided in a convex design facing each other.

As another measure to create a high clamping action, it can be provided that the clamping device, at least in some areas, covers the sensor element in a plane transverse to the direction of the reciprocating movement of the sensor element. Due to this measure, even with a changing position of the ribbon, a reliable clamping action can be achieved.

In one of the preferred embodiments of the base ribbon control device of the invention, it is provided that the sensor element has a head and a shank, a passage for the base ribbon being made in the head, and the base ribbon can be clamped between the head and the clamping device when the sensor element approaches its original position. Such a sensor element is cheap and accurate to manufacture, while also the clamping forces arising between the sensor element and the clamping device are well defined.

In one preferred embodiment of the invention, the shank is axially displaceable. The axial mobility of the shank determines the direction of the reciprocating movement of the sensor element between the initial position and the working position as linear motion. This linear motion can simply be detected by the detector, which is why in this embodiment it is preferable that the detector detects the proximity of the sensor element to its initial position in the position of the shank.

In order for the base ribbon control device to adapt to different ribbon weights and ribbon stiffnesses, in one preferred embodiment of the invention it is provided that replaceable weights can be attached to the head, preferably weights from 10 g to 100 g, or the shank is interchangeable and shanks are provided with various weights, preferably weights from 10 g to 100 g. The attachment of the weights or interchangeable shanks to the head can, for example, be carried out by inserting, screwing or gluing.

High clamping action between the sensor element and the clamping device is achieved when the head has a shape tapering in the direction of the initial position, while it preferably has a narrowing angle (α) from 5 ° to 120 °, even more preferably from 5 ° to 60 °. In other words, in this embodiment, the head is made in the form of a “wedge”, whereby the ribbon of the base is “wedged”. The smaller the narrowing angle, the naturally higher the clamping force achieved; the lower limit of the angle of narrowing is achieved when the sensor element tends to become stuck in the clamping device. The upper limit of the angle of narrowing is reached when the achieved clamping forces become too small.

Preferably, the head is made of ceramic material because it is durable and wear-resistant.

The material for the shank is preferably metal, preferably steel, because it can be processed well and cheaply and is suitable for a wide variety of detectors.

To ensure a stable direction of the moving ribbons of the base, guides of the base ribbons can be provided, which, when viewed in the direction of the reciprocating movement of the sensor element, are located on the side of the sensor element, while the sensor element can move between the guides of the ribbon ribbons.

In addition, it is proposed to use detectors based on the optical, electrical or magnetic principle in the inventive ribbon control devices of the base. Such detectors can be made, for example, in the form of light shutters, in the form of switches, while the sensor element shorts or disconnects the switching contacts, or in the form of inductive or capacitive devices, while the displacement of the sensor element affects the inductance or capacitance.

During operation of a round weaving machine, fluctuations in the tension of the warp ribbon constantly occur, which have nothing to do with the consumption of the warp of the warp ribbon, but are caused promptly, for example, when the edge coil of the warp of the warp ribbon falls down on the axis of the spool and thereby causes a short-term, transitional a drop in tension, which, however, is eliminated by itself when the ribbon of the warp was pulled into a round weaving machine by the length of the loop that fell down. In such cases, in order to prevent a misinterpretation of the loss of tension of the base ribbon as reaching the end of the ribbon of the base, in accordance with the invention, it is provided that the detector provides a signal of the initial position only after it has detected the presence of the sensor element in the initial position for a given period of time. Due to this measure, temporary vibrations of the ribbon of the base, which cause the sensor element to move to its original position or close to it, are not interpreted incorrectly as a ended coil of the ribbon of the base. This proposed measure can also be entered into software (for example, in management).

In order to minimize the laboriousness of laying cables, the base ribbon control device of the invention may provide that a single detector detects an initial position of a plurality of sensor elements.

The invention is now explained in more detail with reference to the drawings.

Figure 1 shows a first embodiment of the inventive device for monitoring the ribbon base in side view.

Figure 2 shows a detail of the first embodiment of the inventive device for monitoring the ribbon base in side view.

Figure 3 shows another detail of the first embodiment of the inventive device for controlling the ribbon base in front view.

Figure 4 shows a first embodiment of the inventive device for controlling the base ribbon in perspective.

FIG. 5 shows an alternative embodiment of a sensor element of a base ribbon control device.

FIG. 6 again shows another embodiment of a sensor element of a base ribbon control device.

7 shows the sensor element of FIG. 6 with another clamping device.

On Fig shows a round weaving machine, equipped with the proposed invention, the control device of the ribbon base, in a schematic side view.

FIG. 9 shows a detailed view of the round weaving machine of FIG.

Figure 10 shows a detailed view of the round weaving machine of Fig. 8, in which the inventive device for controlling the ribbon of the warp are located in other places.

Figure 1, 2, 3 and 4 shows the first embodiment of the proposed invention, the device 1 control tape base for weaving machines, in particular for round weaving machines. First, reference is made to FIG. 1, in which a side view shows two adjacent base ribbon control devices 1, and FIG. 4, which in perspective shows a plurality of base ribbon control devices 1 arranged in two rows next to each other and one after another . Each base ribbon control device 1 includes a sensor element 2, which has a passage 3a for the base ribbon K1, K2. The sensor element 2 can reciprocate between the initial position R, in which it has a prestress due to gravity, alternatively due to the tension of the spring, and the working position A, to which it can be displaced due to the tension F passing through the passage of the ribbon K1 K2 basics. The sensor element 2 is supported in the guide 7 with rotation lock.

In Fig. 1, the sensor element 2 of the right base ribbon control device 1 is in the initial position R. The base ribbon K1 drawn by the dashed line comes to the top right of the not shown creel ribbon of the base or Navoi ribbon, changes direction on the upper roller 10 and lower roller 11, then moves through the passage 3a of the sensor element 2, then it moves to the first rod-shaped guide 12 of the base ribbon, on which it again changes direction, then moves further along the second rod-shaped guide 13 of the tape ki warp, and finally, bypass roller 14 into an unshown circular loom. It should be noted that the sensor element 2 is in the initial position R because the ribbon K1 of the base with its end has already come off its not shown coil of the ribbon of the base and therefore is no longer under tension.

In Fig. 1, the sensor element 2 of the left base ribbon control device 1 is in the working position A. The base ribbon K2 drawn by the solid line comes to the bottom right of the base ribbon or base tape not shown, on the lower roller 11 changes direction, then moves along the first guide 12 the ribbon of the warp through the passage 3a of the sensor element 2, then moves further along the second guide 13 of the ribbon of the warp, and finally, along the bypass roller 14 into a circular loom not shown. It should be noted that the sensor element 2 is in the working position A because the base ribbon K2 is under tension F, which is caused, on the one hand, by pulling it into a round weaving machine, and on the other hand, by the counteracting force of the base ribbon coil, onto which K2 warp ribbon wound.

The upper and lower roller 10, 11, as well as the first and second guide 12, 13 of the base ribbon, when viewed in the direction T of the reciprocating movement of the sensor element 2, are located on the side of the sensor element 2, while the sensor element 2 can move between the guides 10 , 11, 12, 13 ribbons of the base.

Each base ribbon control device 1 also includes a starting position detector 5, which detects that the sensor element 2 is in the initial position R or that the sensor element 2 is close to this initial position R, and when the initial position R of the sensor element 2 is detected or approaches its initial position position R gives a signal 6 of the initial position. 1, the right sensor element 2 is in the initial position R, so that the right detector 5 of the initial position provides a signal 6 of the initial position.

An essential feature of the base ribbon control device 1 proposed by the invention is the base ribbon clamping device 15, 16 formed in this embodiment by two rods for the right base ribbon control device or the base ribbon clamping device 16, 17 for the left base ribbon control device. The base ribbon K1 is sandwiched between the base ribbon clamping device 15, 16 and the sensor element 2 of the right base ribbon control device 1 in the initial position.

Now, reference is also made to FIG. 2, which shows the left base ribbon control device 1 in the enlarged image with a solid line in the initial position R and a dashed line in the working position A. The sensor element 2 includes a head 3 and a shank 4, while the head 3 has a passage 3a for the base ribbon K2. The base ribbon K2 is clamped between the head 3 of the sensor element 2 and the clamping device 16, 17 when the sensor element 2 is approaching its original position, while the head 3 is pushed inside the clamping device 16, 17 formed from two rods, the two rods being parallel to each other to a friend at a distance that is less than the width of the head 3, so that the head 3 is stuck between the rods. To increase friction, the rods of the clamping device 16, 17 are each equipped with a clamping surface 16a, 17a made in the form of a friction surface, while, for example, the friction surface of the clamping device 16 is made in the form of a friction coating, such as, for example, a rubber lining, and a friction the surface of the other clamping device 17 is in the form of a surface roughness or notches. The rods have a circular cross section, so that the clamping surfaces 16a, 17a, made convex, facing the surface of the head 3 of the sensor element 2. This gives a very good clamping action.

The shank 4 has a rectangular cross section and is mounted in the rectangular recesses 7a (see also FIG. 4) of the guide 7, but with the possibility of reciprocating movement (double arrow T) along its longitudinal axis L between the working position A and the initial position R. Visible that the passage 3a for the base ribbon K2 in the sensor element 2 is made across the direction T of its reciprocating movement between the initial position R and the working position A. In the front view of FIG. 3, which is now also referred to, it is clearly seen that the passage 3a for the ribbon K2 of the base is made in the head 3 of the sensor element 2 in the form of a groove open on the side (3c). This allows you to hang the ribbon base, saving time in preparing the weaving machine for use. In this embodiment, the detector 5 detects the proximity of the sensor element 2 to its initial position R at the position of the shank 4. The detector 5 can be based on the optical, electrical or magnetic principle and, for example, be made in the form of a light shutter or switch, while the shank 4 the sensor element 2 shorts or disconnects the switching contacts in the detector 5, or in the form of an inductive or capacitive detector 5, while the shift of the shank 4 of the sensor element 2 is detected, which affects t for inductance or capacitance.

A replaceable weight 3b is attached to the head 3, which is preferably 10 g to 100 g, and weight 3b can be secured to the head 3 by inserting, screwing or gluing. In addition, the shank 4 can also be interchangeably connected to the head 3, and shanks with different weights, preferably weighing from 10 g to 100 g, can be provided. The shank 4 can be attached to the head 3, for example, by inserting, screwing or gluing . Thanks to these replaceable weights, the sensor element can adapt to different weights and stiffnesses of the ribbon.

The head 3 has a shape tapering in the direction of the initial position R, while it preferably has a narrowing angle (α) from 5 ° to 120 °, even more preferably from 5 ° to 60 °. The smaller the narrowing angle α, the higher the clamping force achieved. However, if it is selected less than 5 °, there is a danger that the head 3 will become stuck in the clamping device 16, 17.

Preferably, the head 3 is made of ceramic material. The shank 4 is made of metal, preferably steel.

Figure 4 shows that in connection with the occupied space, the plurality of sensor elements 2 are located in the guide 7 in two parallel rows and offset from each other. This arrangement of the sensor elements can be expediently applied in order to detect, by means of a single detector, the location of the plurality of sensor elements in the initial position. For this, the detector is made in the form of a light shutter and is positioned so that one detector detects a number of sensor elements. For this, the light shutter is arranged so that in the working position of all the sensor elements of this row the light shutter path does not interrupt; but when only one sensor element falls into its original position, it falls into the path of the light of the light shutter. With the arrangement of all sensor elements in two parallel rows, it is thus possible to get by with only two detectors.

Fig. 5 shows a side view, similar to Fig. 2, of an alternative sensor element 22, which differs from the sensor element used in Fig. 2, only in the shape of the head 23. The head 23 is made, in particular, with concave outer surfaces 23a, 23b, which facing the convex clamping surfaces 16a, 17a of the clamping device 16, 17. The sides of the narrowing angle α should be considered tangents at the points of contact between the outer surfaces 23a, 23b and the clamping surfaces 16a, 17a. The other parts correspond to an embodiment of the base ribbon control device 1 of FIG. 1 to FIG. 4 and are also numbered with the same reference signs.

Fig. 6 shows a side view of another alternative sensor element 32, similar to Fig. 2, which differs from the sensor element used in Fig. 2, only in the shape of the head 33. The head 33 in its lower part is made disc-shaped, so that it has a convex outer a surface 33a that faces the clamping device 34, 35. In this embodiment, the clamping device 34, 35 is made in the form of two parallel beams with a rectangular cross section that define flat clamping surfaces 34a, 35a, inclined to each other. The tangent angles at the points of tangency between the outer surface 33a and the clamping surfaces 34a, 35a should be considered as sides of the narrowing angle α. The remaining parts correspond to an embodiment of the base ribbon control device 1 of FIGS. 1-4 and are also numbered by the same reference signs.

FIG. 7 shows a sensor element 32 in conjunction with a clamping device 16, 17 shown in FIGS. 1-4, which is formed by two spaced rods with a circular cross section. In this embodiment, both the clamping surfaces of the clamping device and the surface of the sensor element in a convex design are facing each other.

On Fig shows a schematic side view of a circular weaving machine 100. A detailed view of a circular weaving machine 100 is shown in Fig.9. To the left and right of the round weaving machine 100 is located on the creel 101. On each creel, there are many coils 102 of the warp ribbon, from which the warp ribbons K can be individually pulled out and by various devices for changing direction, such as the bypass roller 14, to be fed to the round bead 105 of the circular loom 100. The circular loom also has a main drive 103 and a control device 104, the main drive 103 driving the movable elements of the round loom 100, and the control device 1 04 electronically controls all the functions of the round loom 100. The principle of operation of such a round loom is well known to the person skilled in the art and therefore does not require a more detailed explanation. A feature of this round weaving machine 100 is the location of the invention of the base ribbon control device 1 on the path of the base ribbon K between the coils 102 of the base ribbon and their retraction into the circular weaving machine 100. In the images of FIGS. 8 and 9, the base ribbon control device 1 is located near the take-off roller 14. It is essential that the signals 6 of the initial position of the base ribbon control devices 1 are transmitted to the control device 104. When the control device 104 receives the initial position signal 6, it stops the main drive 103. Due to this, the round weaving machine 100 comes to a stop state and the attendants can replace the empty base ribbon reel 102 on which the base ribbon K has completely run out, while losing its tension as a result of which, in turn, the provided sensor element 2 has taken its initial position and the base ribbon control device 1 has supplied a signal 6 of the initial position.

However, sometimes it happens that the individual turns of the ribbons K of the base fall from their coil 102 of the ribbon of the base down onto the axis of the coil. This applies, in particular, to the coils located at the edges of the base ribbon coil 102. This falling down of individual screws of the ribbon of the base also has no negative consequences, and a weak turn is gradually reeling up. However, falling down the turn of the ribbon of the base leads to a temporary loss of tension of the corresponding ribbon of the base. In such cases, to prevent a misinterpretation of the loss of tension of the base ribbon K as the consumption of the base ribbon coil 102, it is provided that the detector of the base ribbon control device 1 supplies a signal 6 of the initial position only when it detects the presence of the sensor element in the initial position for a predetermined time period . Due to this inhibitory measure, temporary fluctuations in the tension of the ribbon of the base, which cause the displacement of the sensor element to its original position or close to it, are not taken into account. This measure can also be entered into the software in the control device 104 when this device is programmed to respond to the initial position signal 6 only when it has received it for a predetermined period of time.

Figure 10 shows a detailed view of the round weaving machine of Fig. 8, on which the inventive device 1 control ribbon warp placed directly on the creel 101.

Claims (19)

1. The device (1) for monitoring the warp ribbon for weaving machines, in particular round weaving machines, comprising a sensor element (2, 22, 32) having a passage (3a) for the warp ribbon (K, K1, K2), the sensor element (2, 22, 32) is arranged to reciprocate between the initial position (R) in which it has a prestress and the working position (A) to which it is able to move due to the tension (F) passing through the passage of the ribbon (K, K1, K2) of the base, and containing the detector (5) of the initial position, which the second one detects that the sensor element (2, 22, 32) is in the initial position (R) or the sensor element (2, 22, 32) approaches the initial position (R), and when the initial element (R) of the sensor element is detected (2, 22 , 32) or its approach to the initial position (R) gives a signal (6) of the initial position, characterized in that it contains a clamping device (15, 16; 16, 17; 34, 35), configured to clamp the ribbon (K, K1 , K2) the base between it and the sensor element (2, 22, 32) when the sensor element (2, 22, 32) moves to its original position (R). 2. The base ribbon control device according to claim 1, characterized in that the passage (3a) for the base ribbon (K, K1, K2) of the base in the sensor element (2, 22, 32) is made across the direction (T) of its reciprocating movement between the starting position (R) and the working position (A). 3. The control device ribbon basics according to claim 1 or 2,
characterized in that the passage (3a) for the ribbon of the base in the sensor element (2, 22, 32) is made in the form of an open side groove (3c). 4. The base ribbon control device according to claim 1 or 2, characterized in that the sensor element (2, 22, 32) is installed without the possibility of rotation. 5. The base ribbon control device according to claim 1, characterized in that the clamping device (15, 16; 16, 17; 34, 35) of the base ribbon is provided with a clamping surface made in the form of a friction surface (16a, 17a, 34a, 35a), while preferably the friction surface is made in the form of a friction coating, such as, for example, a rubber lining or surface roughness, or notches made. 6. The base ribbon control device according to claim 5, characterized in that the clamping surface (16a, 17a, 34a, 35a) and / or the surface (33a) of the sensor element (2, 32) facing the clamping surface are convexly facing to each other. 7. The base ribbon control device according to claim 1, characterized in that the clamping device at least in some areas covers the sensor element in a plane transverse to the direction of the reciprocating movement of the sensor element. 8. The basis ribbon control device according to claim 1, characterized in that the sensor element (2, 22, 32) has a head (3, 23, 33) and a shank (4), while in the head (3, 23, 33) the passage (3a) is made for the ribbon (K, K1, K2) of the base, and the ribbon (K, K1, K2) of the base has the ability to be clamped between the head (3, 23, 33) and the clamping device (15, 16; 16, 17; 34, 35) of the ribbon of the base, when the sensor element (2, 22, 32) approaches its initial position (R). 9. The base ribbon control device according to claim 8, characterized in that the shank (4) is mounted with the possibility of displacement in the axial direction (L). 10. The base ribbon control device according to claim 8 or 9, characterized in that the detector (5) detects the proximity of the sensor element (2, 22, 32) to its initial position (R) by the position of the shank (4). 11. The base ribbon control device according to claim 8, characterized in that on the head (3) it is possible to attach replaceable weights (3b), preferably from 10 g to 100 g, or the shank (4) is interchangeable, and shanks with different weights, preferably weights from 10 g to 100 g 12. The base ribbon control device according to claim 8, characterized in that the head (3, 23, 33) has a shape tapering in the direction of the initial position, while it preferably has a narrowing angle (α) from 5 ° to 120 °, preferably from 5 ° to 60 °. 13. The base ribbon control device according to claim 8 or 12, characterized in that the head (3, 23, 33) is made of ceramic material. 14. The base ribbon control device according to claim 8 or 9, characterized in that the shank (4) is made of metal, preferably steel. 15. The base ribbon control device according to claim 1 or 8, characterized by guides (11, 12; 12, 13) of the base ribbon, which, when viewed in the direction (T) of the reciprocating movement of the sensor element (2, 22, 32), located on the side of the sensor element (2, 22, 32), while the sensor element is arranged to move between the guides of the ribbon base. 16. The base ribbon control device according to claim 1 or 8, characterized in that the detector (5) is based on an optical, electrical or magnetic principle. 17. The base ribbon control device according to claim 1 or 8, characterized in that the detector (5) gives a signal (6) to its initial position only after it has detected the presence of a sensor element (2, 22, 32) in the initial position (R ) for a given period of time. 18. The base ribbon control device according to claim 1 or 8, characterized in that one single detector (5) detects the initial position of the plurality of sensor elements (2, 22, 32). 19. A round weaving machine (100), in which it is possible to supply a plurality of ribbons (K) of a warp to a round reed (105), having a main drive (103) and a control device (104), characterized in that it contains control devices (1) tapes of the base according to one of the preceding paragraphs, the signals (6) of the initial position of which are transmitted to the control device (104), and the control device (104) of the occurrence of the signal (6) of the initial position stops the main drive (103).

Images