Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
  • B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
  • B65H59/00—Adjusting or controlling tension in filamentary material, e.g. for preventing snarling; Applications of tension indicators
  • B65H59/40—Applications of tension indicators
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
  • B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
  • B65H2701/00—Handled material; Storage means
  • B65H2701/30—Handled filamentary material
  • B65H2701/31—Textiles threads or artificial strands of filaments

Definitions

• the invention relates to a thread detector according to the preamble of patent claim 1.
• An example of a place of use of such a thread detector is the thread path between a weft thread delivery device and the shed of a weaving machine.
• information about the current thread tension of the stationary or running thread and additional weft monitor information about thread running / stopping conditions are required.
• the thread tension is additionally also scanned, specifically by means of a single deflector and a single, for example piezoelectric transducer.
• An equivalent weft monitor for both functions is also known from US 4,228,828 A.
• Clear and meaningful output signals for the two functions can be to obtain the deflector only with a relatively high level of electronic effort, which contributes to the high cost of the thread detector and its susceptibility to faults, because the requirements for monitoring the thread running / stopping conditions are different from the requirements for measuring the thread tension.
• the invention has for its object to provide a thread detector of the type mentioned, which determines the required information in a different way and better adapted to the respective requirements, derives with low mechanical stress on the thread, is inexpensive and reliable to manufacture and a very wide Application area (for various types of thread processing systems or weaving machines and delivery devices and all thread qualities used in practice) is able to cover.
• each deflector optimally scans the thread with regard to a special requirement and for the task assigned to it (thread tension measurement and / or running / stopping conditions). For this reason alone, each deflector can also cooperate with a relatively simple converter device which is tailored to the respective function. If one function fails, the other function remains unaffected. Since the two deflectors divide the thread deflection among themselves and act like a single form-fitting thread guide, a kind of two-dimensional thread guide, the mechanical load on the thread is moderate and is sufficient for an overall deflection that is significantly less than the sum of the deflections in two completely separate ones Devices for each " function.
• each deflecting surface Due to the angle of less than 180 ° between the deflecting surfaces, each deflecting surface can derive a force component for increasing the pressing of the thread against the other deflecting surface in spite of a small deflecting angle, which improves the responsiveness without the thread Due to the selected geometry, each deflector absorbs just as much of the thread load as is appropriate for the function assigned to it.
• the two deflectors are expediently adjacent in the thread path directly and without contact, so that the force generated on at least one deflection surface from the load acts as directly as possible on the deflection surface of the other deflector.
• the mutual proximity of the deflectors has the advantage that they act together as a single two-dimensional thread guide and effectively stabilize the running thread, which is favorable for the scanning accuracy.
• the angle between the deflection surfaces should be at least essentially 90 °. This ensures clean guidance of the running thread.
• the degree of displacement determines the deflection of the thread in the thread detector.
• the deflecting surfaces of both deflectors are preferably offset with respect to the elongated thread path so that the thread exerts the loads required for scanning on both deflecting surfaces.
• This inclined position is set such that a sliding force component to the deflecting surface of the other deflector is generated from the thread loading on the inclined deflecting surface.
• the deflecting surface of the other deflector is not only acted upon by the reaction force from the deflection of the thread, which can be small there, but also additionally by the sliding force component.
• An inclined angle of approximately 70 ° with respect to the plane mentioned is favorable for the one deflecting surface. With a 90 ° crossing of both deflectors, the inclined angle with respect to the same plane of the other deflector is then approximately 20 °. These angles can be varied.
• the deflector, whose deflection surface forms the inclined angle of approximately 70 ° with the plane, is expediently responsible for the thread tension measurement. Because the thread tension can be more sensitive determine if the thread exerts a significant part of the load resulting from the thread tension on this deflector.
• Deflectors in the form of rods or tubes are simple to manufacture, functionally reliable and suitable for practically all thread qualities. The same outside diameters are useful but not absolutely necessary. Ceramic material has the advantage of high wear resistance and a certain internal damping with low weight.
• the separately operating deflectors are each arranged on a transducer element which is supported in a stationary manner. It is expedient to attach the deflectors with their foot region to the transducer element, so that the loads on the thread are transmitted in an unadulterated manner with a favorable lever arm. Piezoelectric or photoelastic transducer elements are particularly expedient because they deliver meaningful useful signals with moderate control effort. Alternatively, inductive, triboelectric or other transducer elements could also be used, or strain gauges directly on the deflectors.
• each piezoelectric transducer element is integrated in a film chip, which also contains at least part of the evaluation circuit.
• a fluoroscopic photo-elastic transducer element changes its optical properties depending on its deformation or its internal stress state.
• the intensity of the emerging light varies within a wide range and provides meaningful signals that can be easily picked up and evaluated by optoelectronic means.
• the photoelastic transducer element is expediently a plate made of a transparent plastic such as polycarbonate (or an optical glass), which is clamped at least on one side, preferably at both ends, and is almost exclusively subjected to torsion by the deflector.
• This material is largely isotropic in the stress-free state and becomes anisotropic with increasing internal stress, for example a torsional stress.
• This change is followed by the optoelectronic scanning device and output as an output signal, for example representative of the thread tension, and without any appreciable amplification or conditioning effort.
• the optical axis of the scanning device should penetrate the plate perpendicular to its surfaces.
• isochromatic light e.g. Red light from an LED
• the photo-elastic element is illuminated, whereby polarizing elements with crossing polarization axes are used on the input and output sides to set a position in which almost no light is emitted when the element is free of load and the intensity of the emerging light increases with increasing internal voltage a function that can even be linearized with simple control technology.
• the variation in the intensity of the exiting light can e.g. can be tapped with a photo transistor.
• An embodiment of the thread detector is structurally simple with a base body which contains a bearing for the transducer devices and the deflectors as well as the thread guides.
• the deflectors should cross each other without contact.
• the bearing expediently has an inclined position about the thread axis, so that the load on the thread on the at least one deflector results in an increased adaptation against the deflecting surface of the other deflector and increases the response behavior of the thread detector, so that overall a small deflection angle in the thread detector can be selected ,
• 1 is a perspective view of a thread detector
• FIG. 2 three schematic representations of detail variations to the thread detector of Fig. 1, and
• FIG. 5 shows a further detailed variation in a perspective schematic view.
• a thread detector F in FIG. 1 is intended for use in thread processing systems, for example for use in the thread path between a weft thread delivery device and a weaving machine.
• the thread detector F can optionally measure the thread tension and / or monitor the thread running / stop condition of the weft thread.
• Each function is carried out independently. If necessary, one of the two functions can remain unused without affecting the other function. Of course, both functions can be carried out permanently next to each other.
• the thread detector F in FIG. 1 has a base body 1, in which a bearing 2 for two transducer arrangements W is mounted in correspondingly shaped receptacles 3.
• a bridge-like holder 7 supports two thread guides 8, which define the thread path through the thread detector F. 4 with a surface of the holder 7 is designated, which can be assumed as a horizontal reference plane for easier explanation.
• a transducer element 20 is mounted in a stationary manner, for example a piezoelectric transducer element or a photoelastic transducer element.
• a first deflector D1 and a second deflector D2 are each projecting on one side, for example in the form of a round rod or round tube 5, for example made of ceramic material.
• the converter elements 20 are connected to an electronic evaluation circuit 6, from which output signals i1, i2 are supplied.
• the evaluation circuit 6 can be accommodated in the base body 1.
• the converter elements 20 are integrated in film chips that already contain at least part of the evaluation circuit.
• the two deflectors D1, D2 are arranged one behind the other in the thread path without touching one another.
• Each deflector D1, D2 forms a deflecting surface 9, 10 for the thread Y supported by the thread guides 8.
• the deflecting surfaces 9, 10 form an angle ⁇ with one another, which is illustrated by the bearing 2, for example an angle of approximately 90 °.
• the thread Y is deflected between the thread guides 8 on both deflecting surfaces 9, 10.
• the actual, deflected and solid line shown with the fictitious, stretched and dash-dotted thread path defines a plane E.
• the second deflector D2 can be oriented vertically to the surface 4 or, as shown, with a crossing angle ⁇ of approximately 90 ° to the first deflector D1 with the bearing 2 in FIG be slanted at the top right.
• the inclined angle ⁇ can be changed, for example, by an adjusting device 22 in the base body 1 on the bearing 2 as required.
• Deflector D1 with its transducer element W is useful for measuring the thread tension.
• Deflector D2 on the other hand, is used to monitor the thread running / stopping conditions.
• the first and second deflecting surfaces 9, 10 share the total deflection of the thread.
• the deflection surface 9 can be subjected to a greater force by the thread Y than the deflection surface 10.
• the first and second deflecting surfaces 9, 10 on both deflectors D1, D2 are offset from the fictitious stretched thread path defined by the thread guides 8, so that the one that is guided in the angular bend between the two deflecting surfaces 9, 10 and on both Deflection surfaces 9, 10 deflected thread from its Load on the deflectors D1, D2 develops a sliding force component K directed at least in the direction of the orientation of the first deflection surface 9 toward the other deflection surface 10, which increases the contact pressure on the other deflection surface 10.
• a thread section 11 of the thread Y extending to the first deflection surface 9 runs upwards and slightly to the left in FIG. 2, is deflected at the first deflection surface 9, then changes over to the second deflection surface 10.
• the thread Y is deflected on the second deflection surface 10 and also pressed against it with the component K, and runs with a running section 12 to the other thread guide 8.
• the second deflection surface 10 is vertically aligned with the elongated thread path defined by the thread guide 8.
• the first deflection surface 9 is tilted to the right at an inclined angle under relative to the plane E, so that the deflected tapering thread section 11 develops a rightward sliding force component K from the load on the first deflection surface 9, which additionally presses it onto the second deflection surface 10.
• the two deflectors D1, D2 are arranged with one another at an intersection angle of approximately 90 °.
• the first deflector D1 is inclined to the right at an inclined angle ⁇ (for example 70 °) with respect to the plane E, so that the tapering thread section 11 on the first deflection surface 9 develops the sliding force component K to the right towards the second deflection surface 10 and the running thread section 12 against presses the second deflection surface 10.
• the running thread section 12 is also deflected by the oblique position of the second deflector D2 on the latter.
• a photoelastic transducer element 20 is indicated as the transducer arrangement W of the deflector D1, for example.
• This has the shape of a thin, elongated plate 13 and consists of photo-elastic material, for example plastic or optical glass, which is largely isotropic, for example, in the stress-free state. With increasing internal tension, this material changes its optical properties, for example in the anisotropic direction, which can be converted into a clear output signal by fluoroscopy, for example with isochromatic light. The intensity of the emerging light changes and can be scanned in order to infer the tension condition and indirectly the thread tension.
• the plate 13 is clamped stationary at 14 at both ends, for example.
• the deflector D1 is fastened to the plate 13 and projects freely on one side, so that the load exerted on it by the thread Y in the plate 13 produces pure torsion, i.e. internal torsional stresses.
• An optoelectronic scanning device T is provided between the fastening of the deflector D1 and a chuck 14, by means of which the change in the optical properties of the plate 13 is sensed with fluoroscopy (or reflection).
• the optoelectronic scanning device T has an optical axis 21, which penetrates the plate 13 approximately perpendicular to its surfaces 17.
• On one side of the plate 13 there is a light source 15, e.g. placed a red light LED which e.g. emits at least quasi-isochromatic light.
• a first polarizing element 16 with a linear polarization axis defined in the direction is placed in front of the surface 17 of the plate 13.
• a second polarizing element 18 is placed on the opposite surface 17 of the plate 13 in such a way that its linear polarization axis crosses the polarization axis of the first polarizing element 16.
• a receiver 19, for example a photo transistor, is placed in the light path behind the second polarizing element 18.
• the relative positions of the polarizing elements 16, 18, possibly also relative to the optical light transmission axis of the plate 13, are set, for example, such that no light emerges when the plate 13 is in a voltage-free state, since the light waves are extinguished, for example because of the birefringence effect of the polarizing elements.
• the intensity of the emerging light increases according to a mathematical function, for example with the square of the torque applied by the deflector D1, which the receiver 19 registers.
• an output signal, eg i1 is provided representative of the current thread tension.
• the two deflectors D1, D2 are formed with deflection surfaces which are straight across the thread axis. The deflection surfaces could also be concave or convex. Furthermore, the two deflectors D1, D2 need not be immediately adjacent.
• a small intermediate distance could be set, or conversely even a spatial overlap between the two deflectors, for example by means of corresponding cutouts in the deflectors, so that the two deflecting surfaces 9, 10 thereof are moved closer together than shown.
• the angle included between the two deflection surfaces 9, 10 could also be significantly smaller than 90 ° or larger than 90 °, but not larger than 180 °.
• a total deflection angle of + 15 ° for the thread is sufficient for most thread qualities in order to measure the thread tension precisely and to be able to monitor the thread running / stopping conditions.
• Each function can be switched on or off individually. The failure of one function does not affect the other function.

Landscapes

• Force Measurement Appropriate To Specific Purposes (AREA)
• Looms (AREA)
• Geophysics And Detection Of Objects (AREA)
• Glass Compositions (AREA)
• Coating With Molten Metal (AREA)

Applications Claiming Priority (3)

Publications (2)

Family

ID=7681088

Family Applications (1)

Country Status (6)

Families Citing this family (6)

Family Cites Families (17)

• 2001
  • 2001-04-10 DE DE10117879A patent/DE10117879A1/de not_active Withdrawn
• 2002
  • 2002-04-03 DE DE50201115T patent/DE50201115D1/de not_active Expired - Lifetime
  • 2002-04-03 CN CNB028102851A patent/CN1274573C/zh not_active Expired - Fee Related
  • 2002-04-03 US US10/474,866 patent/US20040188232A1/en not_active Abandoned
  • 2002-04-03 AT AT02732552T patent/ATE276960T1/de not_active IP Right Cessation
  • 2002-04-03 EP EP02732552A patent/EP1377513B1/fr not_active Expired - Lifetime
  • 2002-04-03 WO PCT/EP2002/003692 patent/WO2002083539A1/fr not_active Application Discontinuation

Non-Patent Citations (1)

Also Published As

Similar Documents

Legal Events