KR790001486B1 - Stop device of loom - Google Patents

Abstract

A stopping loom apparatus was described for inserting weft yarn in the open warp when the weft yarn doesn't reach the loom end. The reset pulse could be generated for determining the standard weave length and the number of inserted yarn or cone. The electric power circuit was oepned by the output device and the weft inspection elevice when no weft yarn is detected.

Description

Stopper of the loom

1 is a schematic perspective view of a liquid jet loom,

2 is a schematic side view of a loom mounted with the present invention device,

3 is a schematic diagram of operating a loom stopper,

4 is an output waveform diagram of the a-g signal of the schematic diagram of FIG.

5 is a schematic perspective view of a loom mounted with the present invention device,

6 is a schematic of a circuit for operating the loom stopper,

7 is a schematic perspective view of a loom representing another embodiment of the present invention device,

8 is a schematic diagram of operating the apparatus.

體)(각 급사체의 사장(

長)은 일정하게한다)의 수를 알고, 거기에 따라 간접적으로 제직된 길이를 측정하여, 이에따라 상기 기준을 결정하기 위한 리세트 펄스(reset pulse)를 발생시키도록 함을 특징으로 하는 것이다.The present invention relates to a stopping device of the loom, and when the weft inserted in the inclined opening detects whether the weft is reached to the straight end of the inlet side of the opposite weft, and stops the loom in advance, it is prescribed in advance within a specific reference weaving length. In an apparatus for stopping the loom only when the number of inserted weft abnormalities occurs, the length of the woven fabric, or more specifically, the length of the woven fabric is measured directly, or the number of weft yarns enclosed dead bodies (cone)

(President of each raster)

Know the number of times) and measure the length indirectly woven accordingly, thereby generating a reset pulse for determining the criterion accordingly.

In general, the abnormality of the indentation becomes the groove of the weaving, so that the weft detecting means for detecting the abnormality is associated with the stopper of the loom.

As a means of detecting whether the weft thread inserted into the inclined opening of each time reaches the straight end of the opposite weft inlet side, one or two of two means, electrical and mechanical, is used in combination. Malfunction of the detection means is inevitable, and the so-called process paper that stops the machine because it cannot detect even if the weft reaches the upright, or is considered to have been reached even though the weft has not reached the right The so-called overlook situation which does not stop a machine occurs, a stop mark arises in the case of a process paper, and in the case of an overlook, it becomes a weaving groove and produces the defect of the woven fabric.

As one of the conventional electrical detection methods, the weft yarn is in a steady state as the weft yarn is inserted into the end circuit (AND) by generating a pulse generated by detecting it when the weft yarn is completely inserted and a pulse generated every loom rotation in synchronization with the detection timing. Only when there was no detection of the insertion, that is, when there were no pulses in the weft sensing unit, there was a case for stopping the loom by generating a pulse for stopping the loom at the output terminal of the end circuit.

This device detects the intrusion of loom every time and stops the loom by generating a loom stop pulse immediately in case of inflow defect. Since the stop signal is also included in the stop signal, the loom does not need to be stopped at this signal. When the loom is stopped according to the stop signal, the number of stops increases, resulting in a decrease in the operation rate. It is preferable to reduce the number of stops by selecting the stop signal and stopping the loom according to the selected stop signal because it causes a mark. On the other hand, the groove of the woven fabric is passed when the predetermined number or less per predetermined length is passed, so that the loom can be stopped when the groove per predetermined length reaches the predetermined number.

The present invention focuses on the advantages, by measuring the length of the woven fabric directly or indirectly to detect the predetermined length by detecting the predetermined length of the unit length, and only when the number of false input is a predetermined number of times I stopped it. That is, in the apparatus of the present invention, as an example of a means for directly measuring the length of the woven fabric, an iron fan is installed in the friction roller that winds the woven fabric, and an access switch is installed to access the rotation and the access switch of the friction roller. By means of generating a pulse and stopping the loom when a false negative pulse generated between one cycle of the long-term pulse reaches a predetermined time, and inserting it into the inclined opening as a means for indirectly measuring the length of the woven fabric. The length of the weft yarn was taken as a unit, and the loom was stopped when the number of false defects occurring while the entire amount of the specified weft length was consumed reached a predetermined number of times. As another example, the loom was stopped when the number of false defects generated between the ones of the yarns being consumed by one of the yarns, such as the coron, which supplied the weft yarns inserted into the inclined opening, was reached. For this reason, a plurality of feed yarns, the source of the weft yarns, are connected to the winding end and the winding end of each other, and a filler is installed in the vicinity of the connected place to detect that the yarn of the connected part is drawn out as the weft yarn by the filter. The present invention is applied to a shuttleless loom by operating the apparatus of the present invention so that the loom is stopped when the false negative pulse generated between one cycle of the pulse reaches a predetermined number of times. An example will be described with reference to the accompanying drawings.

1 is a weft detecting means of a liquid-jet loom, in which a weft yarn 1 is gripped by a length measuring roller 3 and a pressure roller 4 which rotates in association with the rotation of the loom in the corner 2 and then the length thereof is measured. The liquid discharged from the nozzle 8 via the gripper 7 after staying in a U-shape until the air flow 5 in a predetermined direction reaches the inlet length in the retention tube 6 generated therein, becomes the indentation length. The weft yarn 1 inserted into the opening S of the inclined 10 formed by the heald 9 by a jet and inserted by the weft of the body 11 is pressed by the last CF, By cutting the weft end protruding from the straight end by the cutter 12, weaving the woven fabric (F).

(13) is flammable by trapping yarns (a, b, c, d) which open and close the end of the inserted weft yarn (1) in synchronization with the inclination (10) by the heald (9 '). As a combustor of capture yarns a, b, c, and d, which is rotated via a pulley 15, a belt 16, and a pulley 17 on a rotating shaft 14 of a loom. The weft detection device used here has electrodes 18 and 19 on the outside of one end of the inclined opening on the opposite side of the nozzle, the electrode 19 is grounded to the loom via the body 11, and the electrode 18 is an insulator ( It is fixed to the body 11 by the bracket 21 via 20, and is connected to the control circuit mentioned later via the electric wire 22. As shown in FIG. Accordingly, the insertion weft 1 contacts the two electrodes 18 and 19 and detects that the weft 1 is inserted to the two electrodes 18 and 19 as a current flows between the two electrodes 18 and 19.

However, the detection device is not limited to the above-described form, and may be used as, for example, a center fork of the user loom, a side fork, and the like.

An embodiment in which the length of the woven fabric is directly measured and the frequency divider circuit is reset based on the same will be described below.

The woven fabric F is pulled by the weaving density regulator 29 constituted by the pressing roller 24 and the friction roller 25 via the breast roller 23 and wound around the woven winding roller 30. Moreover, the iron piece 26 is provided in the outer peripheral end of the said friction roller 25, and the access switch 27 is provided in opposition to this. Thereby, the reset circuit of the frequency divider circuit mentioned later is comprised.

The wires 22 at the electrodes 18 and 19 are connected to the amplifying circuit 31 and the output of the amplifying circuit 31 is connected to one input terminal of the end circuit 32. The other input terminal of this circuit 32 is connected to the approach switch 34 of the pulse generator 33 which generates a pulse once per revolution of the loom, and the access switch 34 is synchronized with the rotation of the loom. The iron pin 36 fixed to the rotating arm 35 to rotate is provided opposite to the trajectory. The pulse generator may be of any type as long as it satisfies the necessary conditions. The output terminal of the end circuit 32 is connected to the frequency divider circuit 37. The output of the access switch 27 is input to the frequency divider 37 as a reset signal. The output of the frequency divider circuit 37 is input to the amplifier circuit 38, amplified and then input to the loom stop circuit. That is, it is input to the electromagnetic relay 39, and the electric relay 39 is made to open the electromagnetic switch 40 of the loom driving power supply.

Next, the circuit will be described. When the weft yarn 1 is in contact between the electrodes 18 and 19, that is, when the weft yarn 1 reaches the opposite side of the nozzle, the output b of the amplifying circuit 31 is It becomes "L" and is supplied to the other terminal of the end circuit 32. As shown in FIG. On the other hand, in the pulse generator 33, the pulse C of " H " is generated in synchronization with the contact of the electrodes 18 and 19 of the weft yarn 1 and supplied to the other input terminal of the end circuit 32. Even if the output of the end circuit 32 is " L ", the circuit connected thereafter does not operate.

If the weft yarn 1 continues to penetrate further, and the weft yarn 1 does not contact the two electrodes 18 and 19 for some reason and no current flows between the two electrodes 18 and 19, the amplification circuit 31 ) Is supplied to one terminal of the AND circuit 32 without changing as it is " H ". In addition, the output d of the end circuit 32 is generated by the pulse C of the "H" of the pulse generator 33 generated in synchronization with the timing of contact with the two electrodes 18 and 19 of the weft yarn 1. Change from "L" to "H".

On the other hand, in the access switch 27, the pulse signal e is transmitted for every predetermined weaving length, and the frequency division circuit 37 is reset every time. Therefore, if the dividing circuit 37 is set so that the output becomes "H" if, for example, two stop signals are input during the signal, the output "H" (b) of the amplifying circuit 31 becomes the access switch 33. When the signal is input to the end circuit 32 in synchronization with the pulse signal c at, the signal d of "H" is input to the frequency divider circuit 37. When the input signal is two circuits, the frequency divider circuit 37 The output f of " H " is amplified by the amplification circuit 38, g is operated, and the electromagnetic relay 39 is operated to open the electromagnetic switch 40 of the loom driving power source to stop the loom. .

Next, another embodiment of the weft detection apparatus will be described with reference to FIGS. 5 and 6 as an embodiment in which the length of the woven fabric is directly measured and the frequency divider circuit is reset based on that. A plurality of weft end grippers 41 are provided at intervals from the end of the woven fabric F on the opposite side of the nozzle, are opened in synchronization with the inclination 10 by the heald, and proceed at the same speed as the inclination 10. do.

The weft detection device is composed of a detection guide 43 which is held on the shaft 42 at the intermediate part and rotated on the shaft, and an electrode 44 which is opposed to one end of the detection guide and is made of a household appliance with a flask. It is. The detection guide 43 has a spring 45 which is grounded to the loom and is added counterclockwise in FIG. 5.

A cutter 46 is provided between the woven fabric F end and the weft end gripper 41. In this embodiment, an electrothermal cutter is used, and the cutter 46 is arrange | positioned so that only one weft of the foremost position, ie, the weft yarn located in the front CF, is left. The other end of the detection needle 43 is inserted between the cutter 46 and the straight end and engaged with the weft yarn in the foremost position to disconnect the contact with the electrode 44.

The circuit of the above embodiment is described as follows. The electrode 44 and the detection guide 43 are connected to the amplifier circuit 47, and the output terminal of the amplifier circuit is connected to the frequency divider circuit 48. The output of the approach switch 27 of the above embodiment is input to this frequency divider circuit as a reset signal. The output terminal of the frequency divider circuit 48 is connected to the amplifier circuit 49 and the output terminal of the amplifier circuit 49 is connected to the electromagnetic relay 50. The electromagnetic relay is configured to open the electromagnetic switch 51 of the power source for direct drive.

Referring to the operation of the loom stop device configured as described above are as follows. A pulse is sent from the access switch 27 to reset the frequency division circuit 48. If the upper mouth is normal, the detection guide 43 and the electrode 44 do not come into contact with each other because the one end of the weft yarn is installed by the woven fabric F and the weft end gripper 41. . Of these, weaving is performed to a predetermined length so that a reset pulse is sent from the access switch 27 to reset the frequency dividing circuit 48. As a result, the frequency divider 48 does not output a stop signal, so that the loom continues to operate.

In the access switch 27, a case where the frequency divider 48 is set to output the stop signal when the stop signal is input twice by the weft detector will be described as an example.

Between the pulses at the access switch 27, if the weft thread does not reach the weft end gripper 41 due to any cause, the weft thread is present in the detection guide 43 due to the retreat of the weft post body 11. Therefore, the detection guide 43 is rotated counterclockwise by the spring 45 to be in contact with the electrode 44. As a result, the output of the amplifier circuit 47 becomes "H" and is input to the frequency divider circuit 48. However, since the stop signal from the weft detector is the first, the frequency divider 48 does not output the stop signal. After that, if the weft is not invaded in the upper mouth, the detection guide 43 is rotated in the clockwise direction by the advancing of the body 11, and is not in contact with the electrode 44, but when the body 11 retreats, the spring is not present. It rotates counterclockwise by 45 and contacts electrode 44. As a result, the amplifier circuit 47 again outputs "H". The frequency divider circuit 48 having two stop signals inputted outputs a pulse of " H ", which is amplified by the amplification circuit 49, and the electromagnetic relay 50 is operated to operate the electronic switch 51 of the loom driving power source. To open. In this embodiment, unlike the above embodiment, a pulse generator and an end circuit are unnecessary.

An embodiment in which the length of the indirectly woven fabric is sensed by measuring the required amount of weft required for weaving, and the frequency divider is reset based on the same will be described below. In addition, the same components as those of the above embodiment are denoted by the same reference numerals.

In FIG. 7, 61 is a yarn feeding stand provided in a frame of a loom, and a plurality of yarns 62 and 63 such as a coron are supported by the yarn feeding bodies 64 and 65 on the stand 61. have. The plurality of yarns 62 and 63 subsequently combine the winding shear and winding ends to form one thread as a whole. (3) is a length measuring roller which sandwiches the weft yarn 66 drawn out from the yarn feeding body with the press roller 4, measures the length, and holds it in the staying tube 6. The weft, once retained, passes through the inclined opening by a nozzle (not shown). As a filler (67), the part of the thread which combined the end of the yarn currently being drawn out and the front end of the next yarn is held at the end, and the electrical contact 68 is installed at the other end, and is rotated freely in the middle. It is supported by the support shaft 69. The rotational track of the electrical contact 68 is insulated by the insulator 71 of the electrical contact 70 and is fixed to the support 72. The electrical contacts 68 and 70 form a reset circuit. The electrical contact 70 is connected so as to be input as a reset signal of a frequency divider circuit described later. The weft detecting means is the same as the embodiment shown in FIG. 1 and FIG.

The wires from the electrodes 18 and 19 of the weft detector may be the same as those of the third degree, but the reset circuit constituted by the electrical contacts 68 and 70 is connected to the frequency divider 37. The output generated as the electrical contacts 68 and 70 are connected to the frequency divider 37 is input as a reset signal.

The operation of this embodiment is described as follows. The weft yarn 66 drawn out from the yarn 62 passes through the length measuring roller 3 and the retention tube 6 into the inclined opening at the nozzle. After the yarns of the yarn 62 are exhausted, Since the end of the 62 is connected with the front end of the feed body 62, and one end of the filler 67 is locked to the portion thereof, the supply of the weft 66 from the feed body 62 to the 63 is exchanged. When the filler 67 is in contact with the weft yarn which has been in contact with it, it is rotated by its own weight, and the electrical contact 68 and 70 are in contact with each other to transmit the reset signal to the frequency dividing circuit 37. That is, each time one exhaust body is consumed, one reset signal is transmitted to the frequency divider circuit. Thus, for example, if the disengagement bad signal is transmitted from the end circuit to the frequency divider circuit 37 three times between the reset signals, the frequency divider circuit 37 is set such that the output becomes "H". When the output " H " is input to the end circuit 32 in synchronization with the pulse signal of the access switch 34, a signal of " H " is input to the frequency divider circuit 37, and when the input signal is three times, the frequency divider circuit 37 is an output of "H" and amplified by the amplifying circuit 38 to operate the electromagnetic relay 39 to open the electromagnetic switch 40 of the direct driving power source to stop the loom.

After that, the new yarn is placed at the position of 62, and the end of the yarn 63 and the front end of the new yarn are connected, and the portion of the yarn is held in the filler. When the reset signal can be sent. Moreover, you may arrange | position in 3 or more parallel rows, without alternately placing a steep feed body as mentioned above, and may provide many fillers in between.

In the above three embodiments, the amplifying circuit of the signal from the weft detection device and the amplifying circuit of the signal from the frequency dividing circuit need not be provided as necessary.

The loom stop circuit may open the direct drive power supply by transmitting the output of the divider circuit to the semiconductor, or may be in any form as long as the direct drive power supply is opened by the stop signal in the divider circuit if necessary.

As described above, in the apparatus of the present invention, a pulse is input to the frequency division circuit every predetermined length of the woven fabric and the frequency division circuit is reset. Weaving to a certain length can continue weaving without stopping the loom.

Therefore, the stop due to the malfunction of the detection apparatus can be prevented to some extent, so that the weaving groove due to the malfunction can be reduced, and the operation rate can be improved because the number of stops is small.

Claims (1)

A reset circuit that inputs the pulse of the weft detection device that generates a pulse when detecting the absence of the inserted weft into the frequency divider circuit, and detects the weaving length directly or indirectly when a certain length of woven fabric is formed. The frequency division circuit is periodically reset by the pulses of the pulse generator. When the pulse input frequency of the weft detector reaches a predetermined value during this period, it is output from the frequency division circuit and the power supply circuit of the loom is opened by this output. Loom stops, characterized in that to make.

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