CZ2007273A3 - Method of measuring weight of fiber strand and apparatus for making the same - Google Patents

Abstract

In the method of measuring the fiber sliver, a plurality of fiber slivers passing through a defined space (10) between a pair of squeegee rollers are monitored, one of which is a press roller. The longitudinal axis of the thrust roller (42) is deflected in a plane passing through the longitudinal axes of the thrust rollers and deflection of the longitudinal axis of the thrust roller (42) is sensed in this plane or parallel to it at least one point. The degree of deflection of the longitudinal axis of the pressure roller (42) is proportional to the weight of the fiber strand. The device for measuring the fiber sliver comprises a pair of tensile rollers, one of which is a press roller (42). A pair of tensile rollers is adapted to pass the fiber sliver through a defined space (10) therebetween. The thrust roller (42) is supported in the frame (1) of the device with the possibility of deflecting its longitudinal axis in a plane passing through the longitudinal axes of the thrust rollers. A non-contacting sensor (16) and / or a contact sensor (11) for measuring the changes in the position of the longitudinal axis of the pressure roller (42) are attached to the pressure roller (42).

Description

Technical field

The present invention relates to a method for measuring the weight of a sliver by monitoring a plurality of sliver fibers passing through a defined space between a pair of stretch rollers, one of which is a pressure roller.

The invention further relates to an apparatus for measuring the weight of a fiber strand comprising a pair of prestretch rollers, one of which is a pressure roller and the pair of prestretch rollers is adapted to pass the fiber strand through a defined space therebetween.

BACKGROUND OF THE INVENTION

Several principles of fiber sliver mass measurement are currently known. Some principles are based on the fact that the weight of a strand is given by its volume. Thus, the volume of the strand is measured, for example by palpating the strand with a hinged arm in a densifier or other defined space.

The swing arm is coupled to an electronic sensor that measures the swing arm deflection. Downstream of the hinged arm and electronic sensor assembly there is an exhaust device that extends the fiber strand through the measuring device.

Further, the principle of measuring the sliver weight based on a change in the dielectric constant of a material is known. The strand of fibers passes between the plates by condensate, and when the fiber strand weight changes, the dielectric constant also changes and with it the capacitor capacitance changes as the strand weight changes.

Also known is a method of measuring the weight of a fiber strand, which is based on the granular optical properties of the fiber strand as a function of weight change. If the fiber strand is illuminated by, for example, infrared light, the intensity of the transmitted light can be measured, and it varies depending on the weight of the fiber strand. For this measurement to be sufficiently accurate, the fiber strand space must be so small that the entire fiber cross-section is monitored by transmitted light.

This puts a resistance to the fiber strand and therefore there must be • 4 • .RS36? 4fcz ·: · behind this optical sensor;

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.. · * · »towing equipment in the immediate vicinity. It is difficult to guide the fiber strand into this optical sensor.

Further, a method of measuring the weight of a fiber strand is known, which is based on the fact that the fiber strand passing through a small aperture exerts a force in the direction of movement of the fiber strand, the magnitude of the force being proportional to the size of the fiber strand. The degree of densification is given by the number of fibers entering the aperture and is therefore directly dependent on the weight of the fiber strand.

The specific beam is stressed by the force thus obtained in the direction of movement of the fiber sliver, the deformation of which is measured, for example by means of resistance strain gauges, and thus indirectly the mass of the fiber sliver is measured. This method of measuring the fiber sliver weight also requires that the fiber sliver removal device be in close proximity to the sensor. Measurement by this principle is unusable where it is not possible to reliably introduce the fiber strand tip into the denser opening and immediately withdraw it by machine.

There is also a known pneumatic method for measuring the weight of a fiber strand.

The strand of fibers passes through a special chamber into which compressed air is supplied. The inlet and outlet openings of the chamber are sealed by a passing strand of fibers. As the fiber sliver weight changes, the degree of sealing of the chamber openings also changes, thereby changing the air pressure in the chamber. The change in this pressure corresponds to the change in the mass of the strand. It is measured with a pressure gauge. This method of measuring the sliver weight has the disadvantage that the measured value represents only the average sliver weight of relatively long fiber length and this information cannot be used in a control system for controlling the weight of the short sliver sections.

Further, a method of measuring the fiber sliver shown in FIG. 0 is known in which the deflection of the pressure roller about the axis of rotation BT that is parallel to the axis of rotation of the pressure roller, i.e. in a plane perpendicular to the axis of rotation of the pressure roller, is sensed. The magnitude of the displacement is proportional to the weight of the fiber strand. In practice, the apparatus utilizing this method is designed such that a pair of rollers is rotatably mounted in bearings, one of the rollers of each pair being provided with a recess disc in its central part, in which a disc formed on the other roller fits. Space. · .FE3514GZ.

The sides and the bottom of the recess on one roller and the front face of the disc on the other roller define the space for the fiber sliver to pass through. The pair of rollers is coupled to the drive so that one of the rollers is coupled to the gear wheels with the engine and the other roller is coupled to it, for example by a gear.

The driven roller of the pair of rollers is mounted such that its longitudinal axis does not change its position during operation of the device. The twin-roller thrust roller is held in the working position by a thrust force, such as a spring or a weight or pneumatically, etc., and this is counteracted by the sliver pressure in the guide means (between the disks) on the rollers. The main disadvantage of this method is that the position of the longitudinal axis of the pressure roller of the pair of rollers is still parallel to the axis of the roller, which is only rotatable. This leads to the fact that the pressure roller cannot be driven by friction of the rollers, but by, for example, gears. These wheels are close to the moving fibers and therefore the gearing is clogged by the fiber drift. The varying distance is also not good for the correct position of the tooth flank.

It is an object of the present invention to provide a method of measuring the sliver weight that provides sufficiently accurate information to control and control the sliver weight and which does not impair the serviceability of the prestretch device.

SUMMARY OF THE INVENTION

The object of the invention is achieved by a method of measuring the weight of a fiber strand, which comprises deflecting the longitudinal axis of the press roller in a plane passing along the longitudinal axes of the elongate rollers and at at least one point it senses the deflection of the longitudinal axis of the pressure roller, wherein the deflection rate of the longitudinal axis of the pressure roller is proportional to the weight of the fiber strand.

This method of measuring the sliver weight enables measurement directly on each pair of rollers in the prestretch device. Preferably, this principle is applied to the output pair of rollers from the prestretch device. There is the final state of the fiber strand and information about its actual weight can be used in »*» * .FS3514SZ.

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9 * control system for feedback adjustment of fiber sliver weight. The realization of this method of measuring the sliver weight has no negative consequences on the serviceability of the prestretch device. It also has no negative impact on the transmission of torque from the drive roller to the pressure roller.

The essence of the fiber sliver measuring device is that the press roller is mounted in the frame of the device with the possibility of deflecting its longitudinal axis in a plane passing through the longitudinal axes of the stretching rollers, the contact roller assembly being associated with a proximity sensor and / longitudinal axis of the pressure roller,

Preferred embodiments of the method and apparatus are described in the description of exemplary embodiments and in the dependent claims.

Overview of figures behind the drawing

The invention is schematically illustrated in the drawings, wherein Fig. 1 shows a pair of prestretch rollers in working position with a non-contact pressure roller position sensor, Fig. 2 shows an embodiment with a pressure roller position sensor that contacts its surface; and a tactile roller position sensor, FIG. 4 shows another embodiment of the pinch roller bearing and positioning of the pinch roller position sensor. Giant. Figures 5 and 6 show methods of supporting the stretch rollers so that their swinging movement corresponds to the weight of the strand and is in the sensed plane.

DETAILED DESCRIPTION OF THE INVENTION

The method of measuring the sliver weight will be described by way of example embodiments of several vartiant fiber sliver measuring devices.

The device for measuring the sliver weight in the illustrated embodiments comprises a pair of substantially parallel stretch rollers which are rotatably mounted in bearings 6 and which are mutually drive couplers, eg by friction gearing 7 realized by a pair of collars 70 and 71 on each of the »

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of stretch rollers. One of the pair of prestretch rollers is merely a rotating roller 41 and the other of the pair of prestretch rollers is a pressure roller 42. One of the pair of prestretch rollers is provided with a recess disk 8 into which a disc 9 located on the other of the pair of prestretch rollers extends. Disc 9 abuts to the bottom of the recess in the disc 8, thus defining a space 10 for passage neznározněného sliver Only rotary roller 41 is coupled with neznárodněným drive and pinch roller 42 is only rotatable roller 41 pressed against force N ^ and N _second This thrust ensures the transmission of torque from only the rotating roller 41 to the thrust roller 42.

Only the pivot roller 41 has a fixed position of its longitudinal axis, i.e. its pivot axis, in the bearings 6, wherein the pressure roller 42 is mounted with a variable position of its longitudinal axis in a plane passing along or parallel to the longitudinal axes of the stretch rollers. The variation in the position of the longitudinal axis of the pressure roller 42 is given in dependence on the magnitude of the thrust forces N1 and N2 and the magnitude of the force from the fiber strand, i.e. the force exerted by the compression of the fiber strand in space 10.

The device is further provided with a measuring device for varying the position of the longitudinal axis of the pressure roller 42 in a plane passing along or parallel to the longitudinal axes of the stretch rollers.

In the embodiment shown in Fig. 1, the pair of stretch rollers is driven by a pair of friction gears 7. The fiber sliver guide space 10 is situated midway between the pair of friction gears 7. In the event that Ni = N ₂ the design results in variability the position of the longitudinal axis of the pressure roller 42 in a plane passing along or parallel to the longitudinal axes of the stretch rollers results in deflection in the A direction without a stable rocking center at one point, since the deflection can occur either symmetrically raising and lowering the pressure roller 42 around points swinging BI and B2. In the embodiment of FIG. 1, a measuring device with a proximity sensor 16, which is associated with the disc 9, is used to measure the variability of the longitudinal axis of the pressure roller 42 in a plane passing along or parallel to the longitudinal axes of the stretch rollers, i.e. , depending on the weight .FÍS35WCZ.

The fiber strand clamped in the space 10 deflects only in a plane passing along or parallel to the longitudinal axes of the stretch rollers, thereby changing its position and the sensor 16 senses this change of position. In this exemplary embodiment, it is difficult to use a contact sensor because the disc 9 rotates, which would cause frictional wear on the contact surfaces of the sensor and the disc 9, and secondly, the magnitude of change in longitudinal axis of the pressure roller 42 outside the disc 9 varies depending on whether -Ιι the pressure roller is raised or lowered symmetrically or oscillates around one of the two points B1 or B2.

The random motion of the longitudinal axis of the pressure roller 42 in a plane passing along or parallel to the longitudinal axes of the stretch rollers in the embodiment of Fig. 1 can be eliminated by an arrangement in which Ni # Ng This arrangement is characterized in that the longitudinal axis, i.e. The pressure roller 42 only oscillates in the direction A about one of the points B1 or B2 of FIG. 1, so that a contact sensor 11 can be applied to a suitable non-rotatable part of the pressure roller assembly 42.

The randomness of movement of the longitudinal axis of the pressure roller 42 in a plane passing along or parallel to the longitudinal axes of the stretching rollers can also be eliminated by the asymmetrical arrangement of the fiber sliver guide space 10 relative to the friction drive 7 of the pressure roller 42. the roller 42 only oscillate in a plane passing along or parallel to the longitudinal axes of the stretch rollers, i.e. in the direction A, around one of the points B1 or B2 of FIG. 1, so that a contact sensor ti can be used for a suitable non-rotatable part of the assembly In this arrangement, both an embodiment in which N 2 and an embodiment in which Ni = N 2 is possible

FIG. 2 shows an embodiment in which the touch sensor 11 contacts a non-rotatable portion of the pressure roller assembly 42, which is subjected to the pressing forces N _? In this exemplary embodiment, the fiber sliver space 10 is located asymmetrically to the friction drive 7. The rocking of the pressure roller 42 in a plane passing along or parallel to the longitudinal axes of the stretch rollers, i.e. in the A direction, is always around a single point B which is on or near the surface of the friction collars 70.71.

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In the exemplary embodiment shown in Fig. 3, the pair of rollers is coupled by only one friction transmission 7. The disc 9 which fits into the recess of the disc 8 is located at one end of the pressure roller 42 and the friction transmission 7 is located at the other end of the pressure roller 42. roller

42 is rotatably mounted in the bearings 6 between the disc 9 and the friction gear 7. On only the rotary roller 41, the friction gear 7 and the recessed disc 8 are situated between the bearings 6. In the embodiment of FIG. and it is possible to use a tactile sensor 11 of the pressure roller 42. Preferably, the tactile sensor 11 is positioned opposite the outer ring of the bearing 6 closer to the disc 9. Here again, the movement of the pressure roller 42 or the tapered roller can be used. its longitudinal axes, in a plane passing through or parallel to the longitudinal axes of the stretch rollers, ie in the A direction, around point B,

In the exemplary embodiment shown in FIG. 4, which is a modified embodiment of FIG. 3, the recess disc 8 is located at the free end of only the rotary roller 41 beyond the bearing 6 and the friction gearing 7 is located at the other end of the only rotary roller 41- Sensing the movement of the pressure roller 42 and / or behind the bearing. its longitudinal axis, in a plane passing along or parallel to the longitudinal axes of the stretching rollers, i.e. in the A direction, is similar to the embodiment of FIG. 3 by a sensor 11 assigned to the outer ring of the bearing 6 closer to the disc

9.

In the exemplary embodiment shown in FIG. 5, a possible measure is shown to additionally provide for deflection of the pressure roller 42 in a plane passing along or parallel to the longitudinal axes of the prestretch rollers, i.e. in the A direction. the apparatus in which the stretching rollers are accommodated is provided with a recess with a pair of parallel guide surfaces 3, wherein the end of the pressure roller 42 is situated in the recess and guided through the recess guide surfaces 3 so that only its deflection in a plane passing through the longitudinal axes of the rollers or in a plane parallel thereto, i.e. in the direction A in which the sensor 11 is set.

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In the exemplary embodiment shown in FIG. 6, another possible measure is shown to additionally provide for deflection of the pressure roller 42 in a plane passing along or parallel to the longitudinal axes of the stretching rollers, i.e. in the direction A. This measure consists in that part of the frame 1 .

the prestretch device in which the prestretch rollers are accommodated is provided with a recess with a pair of parallel guide surfaces 5, the recess having a bearing 6 on the thrust roller 42 guided by the recess so that deflection of the thrust roller 42 is possible in a plane passing longitudinally the axes of the stretching rollers or in a plane parallel to it, i.e. in the direction A in which the sensor 11 is set

In another embodiment (not shown), the pair of stretch rollers is arranged such that the disc 8 is arranged on only the rotating roller 41 and the recess plate 9 is arranged on the pressure roller 42.

A common feature of the exemplary embodiments illustrating this invention is that the individual functional elements are arranged such that, in addition to the rotational movement of the two stretching rollers, one of them is allowed to deflect in a plane passing along or parallel to the longitudinal axes of the stretching rollers. The degree of deflection of the longitudinal axis of this prestretch roller, which corresponds to the weight of the fiber strand, is measured.

The invention is not limited to the embodiments specifically described and described herein, since modifications of the principles of the invention for a particular design, including possible combinations of individual design features, do not go beyond the scope of the invention or beyond the scope of the skill.

Industrial applicability

The invention is applicable in textile technology.

Claims (12)

PATENT CLAIMS A method of measuring the weight of a sliver by monitoring a plurality of sliver fibers passing through a defined space between a pair of stretch rollers, one of which is a pressure roller, characterized in that: 5, the longitudinal axis of the pressure roller (42) is deflected by passing the fiber strand through a defined space (10) between the pair of stretch rollers in a plane passing through the longitudinal axis of the stretch rollers and deflecting at least one point a roller (42), wherein the deflection rate of the longitudinal axis of the thrust pin 10 of the roller (42) is proportional to the weight of the fiber strand. Method according to claim 1, characterized in that a substantially random oscillation of the longitudinal axis of the pressure roller (42) about two points (B1, B2) is sensed. Method according to claim 2, characterized in that the substantially random oscillation of the longitudinal axis of the pressure roller (42) about two points (B1, B2) is contactlessly sensed. Method according to claim 1, characterized in that the oscillation of the longitudinal axis of the pressure roller (42) about a single point (B) is sensed. Method according to claim 4, characterized in that the rocking of the longitudinal axis 20 of the pressure roller (42) about a single point (B) is sensed without contact. Method according to claim 4, characterized in that the oscillation of the longitudinal axis of the pressure roller (42) about a single point (B) is sensed in contact with the stationary parts of the pressure roller assembly (42). An apparatus for measuring the weight of a fiber strand comprising a pair of stretch rollers, one of which is a pressure roller and a pair of stretch rollers adapted to pass the fiber strand through a defined space therebetween, characterized in that the pressure roller (42) is in the frame (1). ) equipment *; / RSS5t4CL 9 is disposed with the possibility of deflecting its longitudinal axis in a plane passing through the longitudinal axes of the stretching rollers, the contact roller assembly (42) being associated with a proximity sensor (16) and / or a touch sensor (11) Measuring device for position change of longitudinal axis of pressure roller (42) 5 Device according to claim 7, characterized in that the pressure roller (42) is mounted in the device frame (1) with the possibility of rocking its longitudinal axis substantially randomly around the point (B1) and the point (B1). Device according to claim 7, characterized in that the pressure roller (42) is mounted in the device frame (1) with the possibility of rocking its longitudinal wheel around a single 10 (B). Device according to claim 9, characterized in that the stretch rollers comprise a space (10) for guiding the strand of fibers asymmetrically arranged with respect to the friction drive (7) of the press roller (42). Device according to any one of claims 7 to 10, characterized in that the pressure roller (42) is provided with a non-rotatable part which is associated with a touch sensor (11) of the measuring device for changing the position of the longitudinal axis of the pressure roller (42). Device according to any one of claims 7 to 11, characterized in that the frame (1) of the prestretch device is provided with a recess with a pair of parallel 20 guide surfaces (3, 5), wherein a stationary part of the pressure roller assembly (42) is situated in the recess.