SU7873A1 - Loom - Google Patents

Description

The present invention relates to a weaving machine and is intended, by separating the impact of a percussion device on a shuttle from a low-speed driving mechanism of a weaving machine, to provide for a shuttle a certain impact force that is constant and independent of the speed of the machine, subject to the coordination of the impact of the shuttle with the position of the parts of the loom associated with it.

In the accompanying drawings of FIG. 1-3 give approximate performance of the specified tasks.

According to FIG. 1, the main drive shaft of the weaving machine is indicated by 1, and the number 2 means a special drive shaft for the impact tool. Both shafts can be rotated completely independently of each other. However, in the exemplary form shown in the drawing, it is assumed that shaft 2 obtains rotation by means of bevel gears 3

from the auxiliary shaft 4, which, in turn, is driven by the shaft 1 by means of a friction gear consisting of a large disc 6 on the shaft 1 and a smaller friction wheel 5 mounted on the shaft 4 in a mobile way, whereby the wheel can be engaged with the big wheel 6 at any point located at a greater or lesser distance from its circumference, after which shaft 2 gets more or less number of revolutions. A shock eccentric 7, fitted with an eccentric 8, is pushed on the shaft 2, freely rotating. Together with this shock eccentric 7, a system of levers acts, which rotates around a fixed axis 9 so that the eccentric with a disc is held in one limit position by a rod 10, whereas in the other limit position the clamping clutch is actuated by the aid of the coupling rod 11, which comes in

coupling sleeve 12, after which the eccentric together with the disc will be in engagement with the shaft 2. The leverage system receives movement, on the one hand, from the fist washer 13 mounted on the shaft 1, and the other side from the curvature disk 8 mentioned above.

So, for example, in the position shown in the drawing, the lever 14 is pushed back by the cam of the washer 13, so that the impact eccentric 7 is freed from locking by the rod 10, but then is driven by rod 11 into the steering with shaft 2. However, after half a turn of the shaft 2, the lever 14 then the bolpge does not rest against the cam, disk 13, pushes the curved disk 8 forward again, due to which the rod 10 is engaged again and, conversely, the rod 11 is pulled out of the coupling. After the shaft 1 makes its full turn, the paw disc 13 will be able to change the lever 14, and repeat all over again. cycle of motion.

According to FIG. 2, a change is made in the sense that both shafts 1 and 2 are arranged concentrically, with the reference point 9 attached to the shaft 1, so that the lever 14, along with the rod 11, rotates together with the shaft 1. Instead of a fist puck, in this case a fixed cam 13 is used. The bar 10 receives its support independently of the lever 14. This lever, at least in the part that corresponds to the rod 10, takes the form of a ring against which the rod 10 rests under the action of the spring 15. By shifting the lever 14, on one side, from the cam 13, and on the other side from the eccentric 8, which sits on the shaft, again together with the impact eccentric 7, the latter, as in the original embodiment, in FIG. 1, alternately to a stop, then, conversely, to the coupling with the shaft 2. At the same time, compared with the design in FIG. 1, an embodiment according to FIG. 2, has the advantage 1; a feature that, at the same speed, lies; both shafts 1 and 2, the shift of the system of levers is greater

has no place. But the same speed of turning; these two shafts bring about the usual state of operation, so that a considerable saving is achieved from the wear of the above-mentioned system of levers.

When the rotational speed of shaft 1 is less than the speed of shaft 2, then it is possible to ACHIEVE that, with each rotation of shaft 1, the impact oris will strike the shuttle, namely, in a certain desired position of the weaving machine. In order to push the shuttle 8 back and out, it is necessary, as always, to implant two shock eccentrics on the shaft, which work relative to each other when biased (in a circle) by 180 °. At the same time, the shuttle receives, according to the well-known structures of machine tools, each time a blow during the time when the crank shaft, which rotates twice as fast as the drive shaft of the weaving pile, and serves to move the batt, made one turn.

In reverse-weaving looms, if necessary, also two shafts with two percussion devices and rotation in different directions can be arranged.

Taking into account that the weaving pack, reviewing the speed of its movement, will change its position to an unequal degree, in the interval between the moment of sticking of an eccentric with the impact shaft and the moment of impact, it is recommended to always and positioning the loom, setting the beginning of the clutch, looking at the speed of the machine, then earlier, then later. For this purpose, the organ of the mechanism that performs the clutch is arranged to be rearranged in order to bring it in a way of installation in conjunction, for example, with the apparatus which is used to set this degree of speed of the weaving machine.

In each case, when the speed of movement of the loom changes, there is also a change in strength.

pressing, with which the weft thread is nailed to the previously finished fabric. In order to avoid uneven places in the fabric, a device is proposed by which mechanical pressure of the baton on the weft thread would be regulated over a wide range, and the change in dynamic effect occurring when the speed changes, upon impact on the weft thread would be balanced by changing the mechanical pressure of the hemp on the weft thread. According to FIG. 3, this is accomplished, for example, in such a way that the crank shaft 16 serving to drive the baton eccentrically rests in the new part 17, which, when turned, can change the distance between the shaft 16 and the weft thread struck by the bat 18. At the same time at low speed, the shaft 16 approaches the weft thread, and at high speed they move away from each other, as a result of which, with a less significant dynamic effect, the mechanical pressure of the helix on the weft thread is greater, and with a more significant dynamic effect skom effect, on the contrary, mechanical pressure oslabevaets. The installation of part 17 when it rotates is automatically dependent on the method of installation of the machine at a corresponding speed of movement, with the connection being entered, for example, with the method of shifting the regulator, which is intended to set the speed of rotation of the machine shaft. If the ratios between the parts are correctly selected, then it is possible to achieve, despite the variable speed of the machine, pressure on

the weft thread to the fabric remained about the same.

Subject matter.

T. Loom, characterized by the use of a rotating shaft 2 (Fig. 1) with an eccentric 7 freely attached to it for the shuttle hook, kept from moving together with the shaft 2 by the rod 10 and interlocking with the same shaft 2 by the rods 10 and And, which the rods 10 and I are controlled by a lever 14 having a fixed axis 9 and under the influence of a cam disc 13 on a rotating shaft 1 on one side and an eccentric 8 connected to an eccentric 7 on the other.

2. The form of the weaving machine described in paragraph 1, characterized by the use of a rotating hollow shaft 1 (Fig. 2) concentrically covering the shaft 2 and carrying the axis of rotation 9 of the lever 14, rejected for release by the eccentric 7 non-iodine fist 13.

3. In the weaving machine described in paragraph 1, the use of gear between shafts 2 1 (Fig. 1), which includes: a pair of bevel gears 8, 4 and a pair of friction wheels 5,6, which allow to change the speed of rotation of the shaft 1 .

4.B characterized in and. n 1-3 weaving machines use a device for nailing the needle with a reed at a different distance from the edge of the product, characterized in that the bat shaft 16 (Fig. 3) is placed eccentrically in the OKO..io, which can be rotated in its axis of the supporting parts 17.