This application claims the priority of German Patent Application No. 103 43 377.5, filed on Sep. 17, 2003, the subject matter of which, in its entirety, is incorporated herein by reference.
The invention relates to a shaft drive system for at least one heddle shaft of a power loom.
For forming sheds, power looms are as a rule provided with a plurality of heddle shafts, each of which has many heddles, arranged parallel to one another, through whose the yarn eyelets the warp yarns are passed. For forming sheds, or shedding, the heddle shafts are moved very rapidly up and down. This is accomplished by shaft drive system, which are also called shaft looms or eccentric looms. So-called eccentric looms generate the up-and-down motion of the heddle shafts from the rotary motion of a drive shaft, and high weaving speeds are attainable. However, such eccentric looms are inflexible. Only to a limited extent is it possible to create patterns or different kinds of bindings. For this reason, shaft drive systems are extensively used in which a pawl coupling is provided between a drive shaft and the eccentric element, for generating the shaft motion.
One such shaft loom is known for instance from German patent disclosure DE 697 02 029 T2. The pawl indexing mechanism located between the eccentric element and the driving shaft is switched on here for each shaft motion—that is, for an upward motion or a downward motion of the shaft, in each case for one-half of one revolution of the shaft. Such shaft looms are very flexible. However, such shaft looms cannot attain the operating speed of eccentric looms. The function of the pawl indexing mechanisms is vulnerable to wear. Increasing the operating speed, however, not only causes pawl wear but also leads to breakage of heddles and shafts.
With the above as the point of departure, it is the object of the invention to create a shaft drive system for the heddle shaft of a power loom that makes a high operating speed possible, yet with little load on its elements and on the heddle shaft connected to it.
This object is attained with the shaft drive system of claim 1:
According to the invention, the shaft motion is defined such that neither a purely sinusoidally oscillating up-and-down motion of the shaft, nor an oscillating motion with stoppages at the top and bottom reversal points is obtained. Instead, not only during the phases of motion but also now during the resting phases of the shaft, phases in which the shaft otherwise typically stops at the top or bottom reversal point, the drive system compels a continuous motion of the shaft. This provision opens up the possibility of reducing the maximum accelerations of the shaft. Avoiding abrupt changes in acceleration leads to smooth running of the shafts, without jolting, and even at high operating speeds this does not induce excessive vibration. The operating speed limit at which shaft and heddle breakage occurs can thus be shifted very far toward higher operating speeds. The corresponding curves of motion to be executed by the shaft can be attained, in a first embodiment of the invention, by means of freely programmable drive systems that move the shaft. A control unit associated with the drive systems demand a high speed from the drive systems during the phases of motion, so as to shift the shaft from one reversal position to the other as fast as possible. This process is necessary for shedding, so as to move warp yarns upward or downward out of the warp yarn plane. Once the shaft nears its intended reversal position, the control unit slows down the shaft drive system power takeoff mechanism, which is formed by connecting rods, for instance, and then when the reversal position is reached allows it to swing back and forth around the reversal position in pendulum fashion. Depending on the dwell time in the reversal position, the pendulum motion can pass through one or more maximum and minimum points (undulation courses). The pendulum motion in the resting phases has the advantage that the shaft drive system can predetermine shaft motions that have lesser acceleration values. For instance, in its course over time, at the transition from one reversal position to another, the shaft motion obeys a harmonic function (sine or cosine), and at the reversal position changes over to a time function at the onset of which the acceleration has the same value as upon leaving the curve segment of the transitional motion. The course of acceleration is accordingly constant. The motion curves (also known as “motion principles”) for the transition of the shaft from one reversal position to the other and for the pendulum motion within the reversal point regions can, in a simple embodiment, be stored in a data memory. The control unit then calls up the various control curves from the data memory and triggers the motor or motors of the shaft drive system accordingly. Alternatively, the control curves may be calculated either in advance or in real time; the calculation may be done, from one instance to another, in accordance with special optimization criteria, depending on given peripheral conditions. Examples of optimization criteria may be that a minimum shed opening time must not be less than a given minimum; that the maximum accelerations must be limited; that abrupt changes in acceleration are impermissible; that the shaft speed must be limited; or that for a given maximum acceleration, a maximum operating speed is calculated. The curves resulting from these optimization criteria can then be buffer-stored and used for triggering the shaft drive system. The pendulum motion of the shaft at the top and bottom reversal point region has the further advantage that by the pendulum motion of the heddle shaft, the tension on the warp yarns can be reduced somewhat, which can make the initial weft yarn course easier.
It is also possible for the motion to be executed by the shaft during the resting phase to be generated or predetermined mechanically. For instance, the shaft can be connected via a coupling system selectively to a first drive system, which generates a constant pendulum motion between the two reversal positions, or to another drive system, which generates the motion that swings back and forth about the top or the bottom reversal position. The switchover is preferably effected during existing synchronous phases. The corresponding coupling may be a coupling that transmits linear motions.
The shaft drive system of the invention may, in another embodiment, have an input shaft which is connected to a rotary drive mechanism and which in the final analysis serves to drive a gear system which generates the reciprocating motion of the heddle shaft. The coupling system provided between the input shaft and the gear system has at least two input elements and one output element, which is connected to the gear system. The input elements, upon pickup of the motion from inside, generate a synchronized motion, at least intermittently. Within these time slots in which there is synchronicity between the two input elements and in which the shaft is not at rest, the bell crank lever can switch over from one input element to the other. Thus the switchover is not perceptible as either a jolt or a shock in the drive train. It is therefore unnecessary to reduce the rotary speed of the input shaft for the switchover. An increased operating speed of the power loom can be attained without excessive wear or shaft or heddle breakage, even if individual heddle shafts have to be activated and deactivated again repeatedly.
In one embodiment of the shaft drive system, the first input element is a clutch disk which is solidly connected to the input shaft and thus executes a uniform rotary motion that is predetermined by the rotary drive mechanism. The second input element is then a clutch disk which executes a rotary/oscillatory motion. In selected angular regions that correspond to the top and bottom reversal points of the heddle shaft, the rotary/oscillatory motion is then briefly entirely or nearly synchronized with the rotary motion of the first input element. This is true regardless of whether the rotary motion or the up-and-down motion involves harmonic or nonharmonic motions. After brief synchronicity, the second input element then rotates back again, and then after a 180? rotation of the first input element it again moves synchronously with the first input element over a certain angular range. These brief phases of synchronous motion between the two input elements can be utilized to switch an indexing pawl or other kind of positive-engagement connecting means, connected to the output element, over from the first input element to the second, or vice versa. If the output element is coupled to the first input element, then the shaft executes its reciprocating motion. Conversely, if the output element is coupled to the second input element, which pivots back and forth by only a limited angle, then the shaft is in its resting phase, in which it executes only a slight oscillatory motion about its top or bottom reversal point. However, it can be shifted out of this oscillatory motion during the brief synchronous phases; the forces of acceleration that occur at the shaft and the gear elements involved, and the resultant loads, are hardly greater than in uninterrupted shaft operation. At the least, no significant abrupt changes in the forces of acceleration occur.
The oscillatory motion of the second input element can be attained by means of a cam drive mechanism which is connected rigidly to the input shaft. However, a cam drive mechanism whose shaft revolves at twice the rpm of the input shaft is preferably used, so that with a single cam disk, both the brief synchronous motion for the top reversal point and the brief synchronous motion for the bottom reversal point can be generated. Alternatively, the oscillatory motion can be generated by electric, hydraulic, or pneumatic drive systems.
As the indexing member, an indexing pawl that revolves with the output element is preferably used, which is to be actuated via at least one and preferably two indexing levers past which it travels. The indexing levers can be directly actuated electrically or pneumatically. However, it is preferable to drive them by a cam drive mechanism via a control coupling. The control coupling can then be actuated with only very slight power levels, and on the other hand, sufficiently strong forces are generated to move the indexing levers. The indexing position may be controlled via fixed control magnets, for instance, and may be formed by a selector prong that is driven to oscillate. The result is a control assembly for the coupling system that responds precisely and can be triggered with little energy.
In an alternative embodiment, the two input elements of the cam disk are formed by cam disks, both of which rotate synchronously with the input shaft and are driven by it. The output element of the coupling system here forms a cam follower, which can be brought alternatively into engagement with one cam disk or the other. The cam follower generates an oscillating motion and is not only part of the coupling system but at the same time is part of a gear system for generating the reciprocating motion from the rotary motion of the input shaft. The switchover of the cam follower by the pickup from one cam disk to the other is done at a rotary position of the cam disks in which their arcs match, so that the motion, picked up here from the one cam disk, is synchronized with the motion picked up from the other cam disk. One of the two cam disks may be embodied such that it generates the motion required for shedding, while the other cam disk is embodied as a reversing point disk and generates the oscillating reversal position motion. As such, it has short synchronized arcs serving solely to take over the cam follower element, and otherwise, it has a profile of the kind that does not generate any shedding motion at the heddle shaft, but only generates the reversal position oscillation. In the simplest case, it is a disk with twice the circumferential oscillation and a lesser radial stroke. Two or more cam disks with different work profiles may also be provided. reversal position disks which generate the oscillating reversal position motion at the cam follower may be disposed between each of these cam disks. Thus it is possible to switch over between cam disks and neutral disks, so that the cam follower performing the pickup either, upon engagement with the cam disk that has the work profile, generates a transitional motion from one reversal position to the other, or, upon pickup of the reversal position disk, a departure motion that oscillates with reduced amplitude about the reversal position or out of the reversal position.
It is furthermore possible to assign each set of disks its own cam follower, and to couple the cam followers selectively with an output shaft. The cam disks then form the input elements of the corresponding cam followers, while the output element of the coupling system is connected to a rod linkage that actuates the heddle shaft.
With this kind of coupling system as well, the drive system of a heddle shaft can be switched on and off without slowing down or shutting off the rotary drive mechanism of the input shaft. Overall, a harmonic or nearly harmonic motion of the heddle shaft is generated not only during weaving, but also upon switching the heddle shaft on and off. This creates the preconditions for high weaving speeds, with only little stress on the machine components involved.
Further details of preferred embodiments of the invention will become apparent from the drawing or the description as well as the claims.
In the drawing, exemplary embodiments of the invention are shown.
In
The motors M1, M2 are controlled by a control unit C, based on a microcontroller, for instance, that is connected to a memory unit M. The control unit C triggers the motors M1, M2 such that the heddle shaft 1 is moved appropriately up and down for shedding. This can be done for instance on the basis of two or more curves K1, K2 stored in the memory unit M; the first curve K1 predetermines the motion of the heddle shaft 1 between its reversal positions, while the second curve K2 predetermines a motion of the heddle shaft 1 within its reversal positions. In detail, the motion of the heddle shaft 1 is effected as follows:
In
For clarification of the usefulness of the reversal point oscillation a the top or bottom reversal point, see
The aforementioned motions of the heddle shaft 1 in the phases of motion B and the resting phases R may also be attained with a mechanical shaft drive system 2 of the kind shown in
As
For each heddle shaft 1, 1a, 1b, the shaft drive system 2 (
The gear system 15 is formed by an eccentric element 17, which via a connecting rod 18 drives the lever 11 (
The coupling system 16 of
It may moreover be expedient for the indexing jack 27 to be embodied in two parts, so that the arm that bears the indexing lug 29 and the arm that bears the indexing lug 30 can rotate about the peg 28 independently of one another. As a result, during the synchronous phase, in which the disks 21, 22 briefly run synchronously, both detent lugs 29, 30 can be snapped into place. The length of time during which both detent lugs 29, 30 are snapped in place may be greater, and in fact must be, because of the spacing of the indexing jack 27 in comparison to the one-piece embodiment. By relief of whichever indexing lug 29, 30 is to be disengaged at the time, this lug can then come free of its detent recess 31, 32 or 33, 34 at the appropriate moment.
The indexing jack 27 is assigned two indexing levers 36, 37 (
For actuating the indexing levers 36, 37, a cam drive mechanism 43 (
While the disk 21 is driven to rotate constantly, the disk 22 is, as noted, driven to rotate and oscillate, that is, to swing like a pendulum. To that end a cam follower 53 (
The shaft drive system 2 described thus far functions as follows:
First, it is assumed that the eccentric element 17 is to rotate constantly. To that end, the indexing jack 27 must constantly connect the disk 21 with the eccentric element 17. If this is to be attained, each indexing lever 36 and 37 must deflect outward each time the indexing jack 27, as a consequence of the rotation of the disk 21, moves past the respective indexing lever. To that end, the control magnets 51, 52 are triggered in alternation such that the selector prong 45 presses the end 47 downward when the indexing jack 27 moves past the indexing lever 36, and that the selector prong 45 presses the end 48 downward when the indexing jack 27 moves past the indexing lever 37.
The indexing faces 38, 39 of the indexing levers 36, 37 extend over an angular region that can be considered an indexing region. The cam follower 53, together with the cam disk 54, forms a pendulum drive mechanism 55. This mechanism impresses a rotary/pendulum motion on the disk 22, and this motion is always synchronous with the motion of the disk 21 whenever the indexing jack 27 is traveling through the indexing regions. This phases of motion are characterized in that the cams of the cam drive mechanism 43 force the end of the cam follower lever 44 outward.
During the phase of synchronized travel of the disks 21, 22, the coupling system 16 can be switched over, by providing that the applicable indexing lever 36 or 37 does not deflect outward. As a result (
Because of the interplay, described above, of the coupling system 16, the heddle shaft 1 is imparted the course of motion shown in
A modified embodiment of the shaft drive system 2 is illustrated in
The cam disks 61, 62, 63 are supported axially displaceably as a packet on the profiled input shaft 12. For the displacement, a control fork 67 and a linear actuator 68, the latter shown only schematically and associated with the control fork, are used.
The cam disks 61, 62, 63, as can be seen for instance from
In
The cam followers 71, 72, 73, 74 are seated pivotably on a rotatably supported shaft 77, which actuates the sword 11 via a lever 78 and a connecting rod 79. The shaft 77 may be embodied as a hollow shaft and can accommodate the coupling system 16, to which one of the cam followers 71, 72, 73, 74 is connected selectively to the shaft 77 in a manner fixed against relative rotation. In this case, the coupling system 16 includes a cylindrical body 81, which penetrates the shaft 16 and is provided with one radially oriented fluid conduit 82 for each cam follower 71–74. Seated in these conduits are pistons 83, 84, whose flattened, partially cylindrical heads serve to actuate coupling rollers 85, 86. These rollers are seated in radial bores of the hollow shaft 77 and can be pressed outward by the pistons 83, 84. They fit in corresponding recesses 87, 88 in the respective cam follower 71–74. By means of suitably selectively accessible radial connections 91, 92, 93, 94 (
A novel shaft gear for harmonic engagement and disengagement of individual heddle shafts and for deriving their motion from the rotary motion of a single input shaft has a coupling system with two input elements 21, 22, 61, 62. While one of the input elements serves to drive the output element of the coupling system 16 permanently, the other input element 22, 62 serves solely to synchronize the output element 17 or 64 briefly with the first input element 21, 61. The switchover takes place in the brief synchronous phases, in selected angular regions that correspond to the top or bottom reversal point of the heddle shaft. For the switchover, such novel shaft drive mechanisms do not require any stoppage of motion for the input shaft or the shaft drive mechanism.
It will be appreciated that the above description of the present invention is susceptible to various modifications, changes and adaptations, and the same are intended to be comprehended within the meaning and range of equivalents of the appended claims.
List of Reference Numerals:
1, 1a, 1b Heddle shaft
95 Heddle
2 Shaft drive system
3 Arrow
4 Power takeoff mechanism (e.g., rod linkage)
5, 6 Points
7, 8 Bell crank levers
9 Tension and pressure bar
11 Sword
12 Input shaft
13 Arrow
14 Rotary drive mechanism
15 Gear system
16 Coupling system
17 Eccentric element
18 Connecting rod
21, 22 Input element/disk
23 Arrow
24 Axis of rotation
25 Arrow
26 Indexing member
27 Indexing jack
28 Peg
29, 30 Indexing lugs
31, 32, 33, 34 Detent recesses
35 Control roller
36, 37 Indexing lever
38, 39 Indexing face
41, 42 Pivot axis
43 Cam drive mechanism
44 Cam follower lever
45 Selector prong
46 Control coupling
47, 48 End
51, 52 Control magnets
53 Cam follower
54 Cam disk
55 Pendulum drive mechanism
56, 57 Springs
60, 61, 62, 63 Input element/cam disks
64 Roller
65 Jack
66 Fluid cylinder
67 Control fork
68 Actuator
71, 72, 73, 74 Cam followers
75, 76 Rollers
77 Shaft
78 Lever
79 Connecting rod
81 Body
82 Fluid conduit
83, 83 Pistons
85, 86 Coupling rollers
86, 88 Recesses
91, 92, 93, 94 Connections
A1, A2 Acceleration
B Phases of motion
C Control system
K1, K2 Curves
M Memory unit
M1, M2 Motors
T0, TU Reversal position, reversal point
BTO Reversal point region
t Time
R Resting phase
R1, R2 Radii
S Synchronous phase
S1, S2 Synchronous regions
ω1, ω2 Radian frequency
Number | Date | Country | Kind |
---|---|---|---|
103 43 377 | Sep 2003 | DE | national |
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5918645 | Froment et al. | Jul 1999 | A |
7017617 | Bassi et al. | Mar 2006 | B1 |
7032624 | Bruske et al. | Apr 2006 | B1 |
Number | Date | Country |
---|---|---|
697 02 039 | Sep 2000 | DE |
0851045 | Jul 1998 | EP |
Number | Date | Country | |
---|---|---|---|
20050056334 A1 | Mar 2005 | US |