CS195768B1 - Weaving loom driving mechanism - Google Patents

Abstract

A loom driving mechanism having at a side frame (1) a main drive unit (4) connected to a transmission shaft (10) mounted at one end in the side frame (1) and extending into the central area of the loom to a clutch box (11) so that power may be distributed from the centre of the loom outwards to a weft beat-up drive system with the advantage that power is transmitted and also cooperates with a transmission with the minimum lag between one side of the loom and the other. The transmission shaft also provides a drive from the centre outwards for the let-off and take-up motions. <IMAGE>

Description

The subject of the invention is a weaving machine drive mechanism.

Weaving machines are usually arranged such that. the individual devices are 'distributed' on both sides of the weaving machine. The sides of the weaving machine are designed as ¹ sidewalls, which together with the main beam form the frame of the machine. Said arrangement is given. by. that the space between the sidewalls is filled with a moving warp or ¹ fabric and the devices involved in the fabric formation directly. These ^also include, for example, warp war, clamp,. slats, drawbars, pressure and warp beams. Therefore, other devices, such as an electric motor, a transmission device, a warp controller, are placed in the. machine side frame. The driving force in the form of torque is transmitted from the electric motor by a system of gears of one side to the main shaft of the machine mounted rotatably in the side. The driving force required for the next drive is taken either in the central part of the main. shaft, or at its end.

A drawback of the arrangement with the power take-up asymmetrical to the main shaft transmission means is virtually impossible to establish a rigid coupling of all the associated devices and to ensure their synchronization.

It has been found that in wider weaving machines having an electric motor and a transmission device located on the opposite side to other cooperating devices, the condition of synchronization of the rigid bond is not sufficiently ensured. Failure to meet the above conditions causes unbalanced force conditions in the individual. of the weaving machine ¹ , which is given by the variable magnitude of the forces, especially in the weft-thrust device and in the shed device during one revolution of the main shaft ^{1 of} the machine. The resulting force peaks cause a disproportionate twisting of the main shaft and burden its drive.

Another one. the deficiency is the emergence. time delays in the operation of those weaving machinery which. they are more distant from the one-sided driving force collection point on the main shaft. due to torsion of the main shaft.

Said. the phenomenon is more pronounced with increasing. speed, increasing the width of the weaving machine and is simultaneously influenced by the transmission of the driving force. A significant improvement is not achieved when comparing the different modes of transmission of the driving force. The main shaft twist value cannot be reduced by the use of resilient or shock absorbing elements.

SUMMARY OF THE INVENTION It is an object of the present invention to overcome these disadvantages or at least to substantially reduce them.

The essence of the invention is that the timing shaft has at its end extending into the central region of the machine a transmission means which is displaceably movable. Said transmission means cooperates with another transmission means fixedly mounted on the drive shaft of the weft biasing device and also cooperates with transmission means fixedly mounted on the auxiliary drive shaft of the shed device. The auxiliary shaft has at one end a set of transmission elements for transmitting the information of the commodity controller and for controlling the warp cylinder a set of other transmission elements coupled to the warp controller. At the opposite end of the auxiliary shaft of the shed device there is a set of transmission elements including a coupling element connecting the auxiliary drive unit to the machine drive assembly.

An advantage of the arrangement according to the invention is to ensure the synchronization and rigid coupling of all the looms of the weaving machine connected to the timing shaft. This eliminates the time difference not only between the parts of one device or the devices placed on one side of the machine, but also the time differences between the movements of the devices located on both sides.

Another advantage is the possibility of increasing the speed and increasing the width of the weaving machine.

Yet another advantage is the ability to independently drive the shed together with the warp regulator and the goods regulator via an auxiliary drive unit in any direction. Said auxiliary drive unit enables, after disconnection of the main drive unit, to drive all the looms of the weaving machine in any direction at a lower speed,

1 shows schematically a plan view of a drive mechanism of a weaving machine, FIG. 2 shows an exemplary arrangement of drive shafts, FIG. 3 shows an alternative embodiment of the invention with a weft breaker, and FIG. weft thrust device.

The frame of the weaving machine is formed by a left side plate 1, which is connected to the right side plate 3 by means of the main beam 2. Outside the left side plate 1, there is a drive unit 4 designed here as an electric motor. The drive unit further passes into the clutch and brake assembly 5, from which, for example, a toothed belt 6 transmits a rotational movement to the countershaft 7. On the countershaft 7, the transmission means 8 is engaged, which engages with another transmission means 9 when said transmission means. For example, the means 8, 9 can be designed as a pinion and a co-meshing gear. The transmission means 8 is mounted on the timing shaft 10 at one end thereof.

The other end of the timing shaft 10 extends into the clutch housing 11, which is generally mounted on the main beam 2 in its central region between sidewalls 1 and 3. Preferably, the clutch housing 11 is movable on the timing shaft 10. The transmission means 12, which in the exemplary embodiment is designed as a gear wheel. The shifting of the transmission means 12 is effected by an electromagnetic device (not shown). In an alternative embodiment, the displacement can be performed by a hydraulic or pneumatic device.

The transferable transmission means 12 transfers the driving force to the first transmission means 13 and the second transmission means 20, which are designed correspondingly with respect to the transferable transmission means 12, in the exemplary embodiment as gears. The first transmission means 13 is rigidly coupled to a drive shaft 14 which transmits rotational movement to the weft biasing device 15 located at the left side 1 and the weft biasing device 16 located at the right side 3. Both weft biasing devices 15, 16 change the rotational movement a beam 19 is attached to the shaft 17 by means of the gladiolus 18. The second transmission means 20 is rigidly connected to the auxiliary shaft 21, which transmits the rotary movement through the transmission means 22, 23 and 24, such as gears At its other end, the auxiliary shaft 21 is connected to the transmission means 27 and 28 in the form of a bevel gear. The transmission means 27 mounted on the auxiliary shaft 21 transmits the movement to the transmission means 28 which is attached to the coupling element 29, here designed as a shaft, perpendicular to the auxiliary shaft 21. The commodity regulator 25 drives the drawbar 26. The device not shown here transmits movement from the auxiliary shaft 21 to the warp control. The shaft 29, located on the right side of the weaving machine, transmits the movement for driving the shed mechanism 30. The shed mechanism 30 drives the shed plates 31, not shown here. it is also operated by an auxiliary drive unit 32, for example by an electric motor.

The weft biasing machine 15 and 16, for example, is designed such that a twin wheel 42 is mounted on the drive shaft 14, which transmits movement by means of a pulley 37, 38 and a jack 39 fixedly connected to the shank 17. The beam 40 carrying the beam 19 extends into the shed 41.

The device according to the invention operates in such a way that, after actuation of the drive unit 4, the driving force is transmitted through the brake and clutch 5 to the toothed belt transmission 8, to the countershaft 7 and the transmission means 8 and 9. When the shiftable transmission means 12 is left in the clutch housing 11 when it is engaged, it transmits rotary movement to the cooperating first transmission means 13 and the second transmission means

20. The first transmission means 13 actuates the drive shaft 14 which carries the twin-wheel 42 and, by means of the rollers 37, 38 and the jack 39, causes the rocker shaft 17, the gladiolus 18 to swing and the functional movement of the spoke 19 thereafter. The transmission means 22, 23, 24 and the goods controller 25 are rotated together with the auxiliary shaft 21. The goods controller controls the movement of the drawbar 26 and thereby controls the removal of the goods. The auxiliary shaft 21 also causes the movement of the warp controller 33, which, via the gears 34, 35, controls the movement of the warp roller. The bevel gear 27, 28 actuates the shaft 29 and hence the shed mechanism 30.

If the drive unit 4 is disengaged by the clutch and brake 5 and the gear 12 is disengaged, as indicated by the arrow in FIG. 1, the shed 30, the merchandiser 25 and the warp regulator 33 are moved in any direction by the auxiliary drive unit. 32. The other movement mechanisms of the weaving machine are at rest.

Leaving the transferable transmission means 12 in cooperation with the first transmission means 13 and the second transmission means.

Claims (4)

A weaving machine gear comprising a drive unit driving a clutch and brake assembly from which rotational motion is transmitted to a timing shaft rotatably mounted in one of the machine side and clutch housings rigidly coupled to the main beam and further comprising a weft breaker assembly, characterized in that the timing shaft (10) has at its end extending into the central region of the machine a displaceably mounted transmission means (12) cooperating with a first transmission means (13) firmly mounted on the shaft (14) of the weft-drive mechanism (15, 16); 20) fixedly mounted on the auxiliary shaft (21) of the shed ¹ drive mechanism (30), which has at one end a set of transmission elements (22, 23, 24) for transmitting information to the commodity controller (25) and for controlling the warp roller (36) a system of further transmission elements (33, 34) coupled to the warp controller at the opposite end of the auxiliary shaft (21) by the water means 20 with the auxiliary drive unit 32 and after disengaging the clutch and brake assembly 5, the auxiliary drive unit 32 drives all the looms of the weaving machine forward. In an alternative embodiment, as shown in Fig. 3, the weft biasing devices 15, 16 are replaced by only one weft biasing device 15, which is preferably located in the clutch housing 11 together with the movable transmission means 12, the first transmission means 13 and the second transmission means. 20. The length of the drive shaft 14 in this alternative embodiment has been shortened and the drive shaft 14 is a short shaft 43 housed in the clutch housing 11 suitably provided. For example, the brake and clutch assembly 5 may be located in the left sidewall area 1. The drive unit 4 may be mounted in tandem with the brake and clutch assembly 5. The torque transmission is carried out in a known manner, for example by V-belts 44. The function of the other components and the way they work remain unchanged. The invention made according to this alternative is particularly suitable for narrow weaving machines. In another alternative embodiment, as shown in FIG. 4, the drive shaft 14 is replaced by a shaft 45 housed in the housing 46 and 47 outside the sidewall of the machine on the main beam 2. The shaft 45 drives movement to the housing 46 in which the weft biasing device 15 is accommodated. and a housing 47 in which the weft biasing device 16 is accommodated. The function of the other devices is maintained as well as the way in which the invention operates. BACKGROUND OF THE INVENTION a system of further transmission elements (26, 27) including a coupling element (29) connecting the auxiliary drive unit (32) to the machine drive assembly is provided. Weaving machine drive mechanism according to claim 1, characterized in that the auxiliary shaft (21) and the drive shaft (14) are spread over the entire width of the machine and are mounted in the sidewalls (1, 3). 3. The weaving drive mechanism of claim 1, wherein the first transmission means (13) mounted firmly on the short shaft (43), together with the short shaft (43) and the weft impact device (15), is housed in a clutch housing located in the central area of the machine between the sidewalls (1, 3). 4. The weaving mechanism of claim 1, wherein the first transmission means (13) is rigidly mounted on a shaft (45) rotatably mounted in housings (46, 47) comprising weft biasing means (15, 16), one housing. (46) is located in the le- 195788 in the middle of the machine between the center of the machine and the body in the right half of the machine between the center of the left side panel (1) and the next cabinet (47) is the machine and the right side panel (3).