CS241316B1 - Weft thread's range doffer for confusorless weaving machines - Google Patents

Abstract

The object of the invention is to detect the arrival of a weft threads of confusion-free weaving machines into the controlled area. The invention is refers to a range stop for unorthodox weaving machines with weft yarn insertion by moving the canal created in proflovane rays. The essence of the invention is in the sensor solution and its positioning on the profiled beam.

Description

The present invention relates to a weft yarn range sensor for non-confluent weaving machines with profiled beam, where it solves the weft yarn arrival into the controlled area and electronic impedance and level adaptation for further processing by means of an evaluation device based on the contactless optoelectronic data acquisition principle.

The known weft yarn sensors for non-confident weaving machines operate on different principles. The mechanical-electronic sensors consist of a mechanical contact which is separated from the switching part by a non-conductive weft yarn material. Sensors on the conductivity principle sense the weft material in such a way that two electrodes, respectively. one is bridged by the weft yarn and the input data for further processing are generated. Piezoelectronic and trieboelectronic sensors are placed on the input portion of the weft yarn cover, while the material by friction on the sensor produces a processable signal.

Optoelectronic sensors work on the reflective principle, i. j. principle of reflection of emitted rays and their intersection by the weft yarn, while these sensors are placed in front of the draining channel, or they scan up to weft material. Another optoelectronic sensor known is a sensor in which the weft material is pushed before being knocked into the controlled area by means of a mechanical device and only then is knocked.

Mechanical-electronic sensors due to high inertia forces and very high centrifugal forces, elongation and vibration cannot operate at higher machine speeds. Sensors on the conductivity principle work on machines with a weft thread cover by means of a conductive medium, e.g. water and cannot process glass and staple yarns. Piezoelectronic and trieboelectronic sensors are used only in machines in which the weft yarn is introduced into the draining channel by means of a barbell or pinch, eventually in needle weaving machines. Optoelectronic sensors on the reflective principle are used for certain types of materials and their reliability for very thin materials is very low. Optoelectronic sensors, which operate on the principle of inserting the weft yarn, send a signal for further processing only after the weft yarn has been reached, and thus. the whole stopping of the machine shifts the demi-technological positions, otherwise the stopping mechanical mechanism of the weaving machine is very stressed.

The aforementioned drawbacks are overcome by the weft yarn range sensor for the non-confined weaving machines according to the invention, which consists of a sensor positioned downstream of the profiled beam, while the sensing portion is pushed through the beam tooth so that it opens into the profile in which the weft yarn moves.

The sensor consists of two parts, a transmitter part and a receiver part. The receiver is located on a beam in the space of the profile serving for clogging the weft yarn. The transmitter is positioned in front of the beam so that it emits electromagnetic radiation towards the beam profile used for clogging the weft yarn, while covering this space entirely. The receiver located behind the beam and pushed through the toothed beam at the weft range check point consists of the receiver or the n-receivers of the electromagnetic radiation, while the transmission of the electromagnetic radiation to the receivers can serve e.g. 1 — n light guides, or directly 1 — n receivers equipped with a shaping orifice.

In the receiver are placed adaptive or evaluation electronic circuits, which are connected to other circuits in the switchboard by an electric cable. The adjusting circuits located below the loom of the weaving machine make it possible to conduct electromagnetic radiation from the transmitter by means of 1-n light guides and also from the profiled beam used to insert the weft yarn to the receivers below the loom of the weaving machine,

When the weft yarn reaches the area controlled by the weft yarn range sensor for non-confluent weaving machines, the weft yarn interrupts the electromagnetic radiation emitted by the emitter directly or respectively. through the light guides, and this creates a voltage pulse on the receiver side, which is further modified and amplified. The voltage pulse is further processed in the evaluation circuits. If an error occurs during the weaving process, If there is no drop in the i th turn, the electromagnetic radiation will not be interrupted and thus no voltage pulse will be generated on the receiver side, the evaluation electronics will evaluate the fabric error, thus creating a stop pulse for stopping the weaving machine. The weft yarn range sensor for non-confined weaving machines can be adjusted to the fabric width and is virtually independent of the machine speed. A further advantage of the weft yarn range sensor for non-confluent weaving machines is that it detects the weft range, and thus the weaving machines can be equipped with stops in technological positions even at very high speeds.

The weft yarn range sensor is shown in the drawings where FIG. 1, FIG. 2, FIG. 3 shows an example of a weft yarn range sensor for a non-confluent weaving machine in the workpiece. In FIG. 1 shows a profiled beam 1 with a profile 2 for inserting the weft yarn into the shed 3, the weft yarn range receiver 4 for the non-confluent weaving machines is located behind the profiled beam 1 and is pushed through the tooth 5 of the profiled beam 1. bidlen 8, as opposed to receivers 4.

WITH

The detail of the range 9 is fitted with sealed light guides 10, which must be polished from both sides. In FIG. 2 is an example of a weft yarn range receiver 4 for non-confluent weaving machines in an uplift in which electromagnetic radiation is guided by light guides 10 and the electromagnetic radiation transmitter S together with the electromagnetic radiation receiver 4 is performed only between the light guides 10. FIG. 3 shows the insertion of the weft yarn arrival receiver 4 for non-confluent weaving machines by the tooth 3 of the profiled beam 1 and 12 shows the weft yarn face. The electromagnetic radiation receiver 4 and the electromagnetic radiation transmitter 6 consist of 1 - n number of elements, the transmission of electromagnetic radiation being provided by 1 - n number of light guides 10.

Claims (3)

SUBJECT A thread-detector for non-confined weaving machines is characterized in that the electromagnetic radiation receiver (4) is pushed by a tooth (5j of the profiled beam (1) at the profile location (2j), the electromagnetic radiation transmitter (6) being located opposite the receivers. (4). 2. A weft yarn range sensor for the invention of a confuser weaving machine according to claim 1, characterized in that the electromagnetic radiation receiver (4) and the electromagnetic radiation transmitter (6) are composed of 1 - n number of elements, the transmission of electromagnetic radiation being ensured by 1 - n number. Fiber optic (10).