KR840000730Y1 - Warp let-off motion in the loom - Google Patents

Abstract

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Description

Inclination feeding device in loom

1 and 2 are schematic diagrams showing conventional braking devices, respectively.

3 and below show a braking device embodying the present invention, and FIG. 3 is a side view showing the entire apparatus of the first embodiment.

4 is a cross-sectional view of the shaking.

5 is a sectional view showing the principal parts of a second embodiment;

6 is a partial side cross-sectional view showing the third embodiment.

The present invention relates to an inclined dispensing apparatus for discharging the inclined wound on the inclined beam in the loom. The warp yarn feeding device of the conventional loom keeps the tension of the warp constantly at all times in order to achieve uniform weaving.

That is, when the gradient change of the slope was detected and the transmission of the gradient transmission device was operated in accordance with this detection, when the gradient tension increased, the delivery speed of the gradient beam was increased and it was reversed in the race having less gradient tension. However, if a momentary tension fluctuation occurs instantaneously when weaving, for example, during a beating operation, if a large tension is applied to the inclination instantaneously, increasing the rotational speed of the inclined beam will increase the amount of delivery so much that the uniformity It becomes impossible. Therefore, it is desirable not to operate the transmission in such a case.

In addition, it is necessary to prevent the change in tension from being transmitted to the transmission even when the loom is stopped, or to prevent the reaction force of the discharging motion from flowing backward to the detection part of the tension change. For this reason, conventionally, as shown in FIG. 1, the brake surface 54 is installed on a part of the lever 53 which interlocks with the transmission, and has a roller 52 for guiding the inclined Y from the inclined beam 51. When a large tension is applied to the inclination Y by installing the lever body 56 with the brake shoes 55 corresponding to the hibernating surface 54, the brake shoes 55 are connected to the braking surface 54 by the force of the spring 57. It is press-fitted to fix the above-mentioned lever body 53 for tension detection, and in other cases, the brake shoes 55 are separated from the braking surface 54 against the counter force of the spring 57 by the action of the cam 58.

In this conventional device, whenever the brake shoes 55 and the braking surface 54 come into contact with each other, a high sound is generated, which is not a cause of noise, but when the force of the spring 57 is weak, the immediate response of the lever body 53 is performed. However, if the spring force is strong and the spring force is used to solve this problem, the electric noise becomes more severe.

As another conventional apparatus, as shown in FIG. 2, the plate 61 provided at a part of the lever 59 by activating the solenoid 60 at a predetermined time with the lever body 59 provided between the inclined tension detecting unit and the transmission always free. Is sandwiched between the fixing part 62 and the gripping lever 63 to make the lever body 59 in an inoperative state so that the operation of the tension detector is not transmitted to the transmission. Therefore, in the conventional apparatus, as in the case of the conventional apparatus described above, the braking part makes contact with each other. Therefore, noise is generated during operation of the solenoid 60, and if the magnetic force of the solenoid 60 is weak, an immediate response, Problems with followability and strong magnetic solenoids resulted in a noise that was louder and consumed more power.

In addition, in this conventional apparatus, the durability is insufficient, and if a braking action is performed every time, the apparatus is damaged and is practically difficult. In addition, the instantaneous, follow-up, or noise generation of the two conventional apparatuses described above is more remarkable in a loom that performs high-speed rotation up to several times of conventional looms such as, for example, a jet loom.

The object of the present invention is to solve the problems of the conventional braking device, and to provide a braking device for an inclined transmission site that is excellent in molar instantaneous response and followability without generating noise accompanying braking. Hereinafter, a first embodiment incorporating the present invention will be described with reference to FIGS. 3 to 5. FIG.

The inclined beam shaft 2 is rotatably supported on the frame 1 of the loom, and the inclined beam 3 is detachably installed on the inclined beam shaft 2. The transmission 4 is arranged on one side of the frame 1, and the power is transmitted from the drive shaft (not shown) to the input side 4a via the timing belt 6 and at the same time according to the rotational displacement of the transmission shaft 4b having the shift lever 5. The rotation speed of the electric power is shifted and output from the output shaft 4c to be transmitted to the inclined beam shaft 2, which is transmitted via the spur gear 7, 8, the bevel gear 9, 10, the worm 11 and the worm wheel 12. In the rear upper position of the inclined beam 3, the frame 1 is arranged so as to be rotated back and guides the inclined Y which is discharged from the inclined beam 3. In the upper position of the inclined beam 3, a pair of left and right tension levers 14 are pivotally supported by the shaft 15, and a tension roller 16 is rotatably installed between the rear ends thereof, and upwards through the 13 from the inclined beam 3 back. The inclination Y is sent to the heald frame (not shown) via the tension roller 16, and the entire tension lever 14 swings about the side 15 in accordance with the tension variation of the inclination Y.

In the lower position of the tension lever 14 described above, the swing lever 17 is pivotally supported by the side 18 at one end of the frame 1, and the connecting rod 19 is connected between the proximal end and the distal end of the tension lever 14. At the same time, between the connecting rod 19 and the tension lever 14, a spring 20 is installed to absorb the momentary large tension or impact applied to the inclined Y at the time of beating and maximum opening.

Balanced weight 21 is attached to the tip of the swing lever 17, and a constant tension is applied to the slope Y via the swing lever 17, the connecting rod 19, the spring 20, the tension lever 14 and the tension roller 16. Between the proximal end of the swing lever 17 and the shifting lever 6 described above, the operating rod 22 is connected, and the swing of the swing lever 17 accompanied by the change in the tension of the inclination Y is transmitted to the shifting side 4b, which is accompanied by the fluctuation of the swing amount. By shifting the shifting shaft 4b, the rotational speed of the inclined beam 3, which was obtained by changing the transmission ratio of the transmission 4, is adapted to the tension variation of the inclined Y so that the optimum tension is always given to the inclined Y. have.

As shown in FIG. 4, a conventional electromagnet 24 having a coil 23 is fixed to the tip of the swing lever 17, and the moving range of the electromagnet 24 corresponding to the swing of the swing lever 17 ), A suction plate 25 made of magnetic material such as iron is fixed to the frame 1 by bolt 26. The electromagnet 24 is in qualitative contact with the adsorption plate 25 which is normally electric.

The operating time of the electromagnet 24 can be chosen by the enemy, for example, during a straight motion, during a big shock such as during a beating, or only when the loom is stopped. Nearly in the middle of the swing lever 17, the scale indicator rod 27 is installed at the bottom thereof so that the upper indicator 27a corresponds to the scale plate 28 fixed to the frame 1 and indicates the swing position of the swing lever 17 due to the tension variation of the inclination Y. have. Thus, during straight weaving, the inclined beam 3 is rotated from the drive shaft via the gear mechanisms such as the transmission 4 and the spur gears 7, 8, and the inclination Y is sent out. As the inclination Y is fed out, the diameter of the inclined beam 3 decreases, so that the amount of delivery of the unit rotational wall decreases, and a stronger tension is applied to the inclination Y. In this case, the tension lever 14 is oscillated by this changed tension, the oscillation lever 17 oscillates via the connecting rod 19, and the transmission 4b is rotated via the operating rod 22 and the shift lever 6.

For this reason, the transmission ratio of the transmission 4 is changed so that the rotational speed of the inclined beam 3 is corrected, so that the inclined Y can always perform a homogeneous texture maintained at a predetermined tension. In this case, even when the swinging lever 17 is swinging, the electromagnet 24 at the tip of the swinging lever 17 is substantially in contact with the suction plate 25. Thus, for example, during the preset beating, the electric 24 is excited and adsorbed onto the suction plate 25, so that the swing lever 17 is in an unstable state.

For this reason, even if the tension lever 14 is oscillated by the impact caused by the beating or the instantaneous tension change of the inclination Y, the oscillation lever 17 is not absorbed by the spring 20 of the connecting rod 19. Therefore, the transmission 4 is not shifted even when shock or a large tension is applied in this way, and does not adversely affect the weaving.

In this case, since the electromagnet 24 is always in contact with the adsorption plate 25 in the moving device, the adsorption and fixation of the adsorption plate 25 simultaneously with the excitation of the electromagnet 24 results in a high instantaneous and almost in contact with the adsorption. And because of this good instant response, there is no need to use a strong magnetic magnet and save power consumption. Next, a second embodiment of the present invention will be described with reference to FIG. In this embodiment, a permanent magnet 29 is always provided in contact with the suction plate 25 at the tip of the swing lever 17, and a coil 30 which generates magnetic flux in the opposite direction to the permanent magnet 29 is provided in a part of the permanent magnet 29. Normally, the swinging lever 17 can swing by canceling the magnetic flux between the permanent magnet 29 and the coil 30 by energizing the coil 30, and interrupting the energization of the coil 30 only when an impact or excessive tension is applied to the permanent magnet 29. The rocking lever 17 is configured to be in an inoperative state by being adsorbed on the suction plate 25.

In the third embodiment shown in FIG. 6, the electromagnet 24 is fixed to the frame 1 and the adsorption plate 25 is fixed to the tip of the rocking lever 17, in contrast to the first embodiment described above.

As exemplified in the above embodiment, the present invention installs a magnetic body on one side of the frame and the swinging lever and installs a magnet in a state where the magnetic body is substantially in contact with the magnetic body on the other side. It is possible to prevent the occurrence of noise due to the excellent effect that can provide a braking device with excellent instant response and durability.

Claims (1)

In the inclined transmission device for controlling the rotational speed of the inclined beam by transmitting the transmission of the tension roller in contact with the inclination in the process from the inclined beam to the heald frame side, the transmission system from the electric tension roller to the transmission Frame And an adsorption member including at least an electromagnet corresponding to the magnetic body placed on one side of the magnetic body and placed on the other side thereof in a state in which the magnetic body is substantially in contact with the magnet body.