Known weaving machines or looms with a so-called electric motor direct drive, i.e. a drive that is not separatable from the main drive shaft of the loom during the running operation, have an operating behavior that is recognizable clearly from the sharply varying loom rotational speed per weaving cycle, among other things.
For the compensation of rotational speed fluctuations of the loom, a drive arrangement for a loom and a shedding machine is known from DE-U 200 21 049.1, wherein at least the main drive shaft of the loom has an additional rotating inertial mass or flywheel mass for the compensation of the rotational speed fluctuations. This additional inertial mass, however, has a negative effect on the acceleration process during the start-up of the loom. This is problematic for applications with high operating rotational speed, especially if the run-up for the loom is required “in one weft insertion” for ensuring the woven fabric quality, that is to say the dynamics already of the first reed beat-up must correspond to the dynamics of the following reed beat-ups. If an additional inertial mass must also be accelerated, this quickly increases the drive power that is to be installed, to a level that is no longer economically justifiable.
In other looms with electric motor direct drive, an inertial mass connected with the main drive shaft is omitted or avoided, in order not to delay or to make-difficult the acceleration process during the start-up of the loom. The avoidance or omission of an additional inertial mass, however, as already discussed above, leads to considerable rotational speed fluctuations per weaving cycle. For the compensation of the rotational speed fluctuations, it is obvious to influence the fluctuations in the rotational speed of the electric motor drive through corresponding controlling or regulating of the supply of electrical energy. Such influencing, however, leads to considerable loading of the drive train of the loom and of the shedding machine. Moreover, such a rotational speed compensation does not lead to an operating manner with energy constancy; the resistive or dissipative heat losses and loading for the motor and power electronics are very high.
It is further known from DE-U 200 21 049.1 to separate the loom and the shedding machine with respect to the drive technology, that is to say to allocate at least respectively one electric motor drive to the main drive shaft of the loom and to the drive shaft of the shedding machine. Associated therewith is the advantage that a rigid synchronization between loom and shedding machine is no longer present; at any time it is thus fundamentally possible to flexibly embody the tuning or adaptation of the operating behavior of loom and shedding machine corresponding to the weaving requirements, that is to say to select the synchronicity of both drive systems with respect to basic tuning or adaptation (for example shed closure at what loom position angle) and with respect to the permissible tolerances within broad limits. This embodiment of the drive synchronicity as desired within broad limits, however, in turn leads to considerable loading of the drive train of the loom and/or shedding machine; and similarly, due to the necessary control or regulating efforts, the resistive or dissipative heat losses and loading of the motor and the power electronics become very high. These disadvantages become still greater because the loading of the electric motor drive of the shedding machine is dependent on the motions of the shedding means (shafts; lifters), thus dependent on the weave pattern or generally dependent on the weaving application.
Now, due to the omission of the previous rigid coupling between loom and shedding machine, however, influences for the tuning or adaptation of the operating behavior of both machines become necessary in such a manner so that the so-called weft insertion window, with reference to the respective operating rotational speed, becomes as large as possible and/or reproduces itself as exactly as possible weft for weft in its time duration and/or development (that is to say how it opens or closes). This requirement arises very essentially in connection with gripper looms, wherein a gripper running character that is poorly tuned or adapted to the weft insertion window leads, for example, to the occurrence that the grippers do enter into the shed at the correct time point, but leave it too late. Thus, the gripper heads and/or the gripper rods rub on the warp threads of the shed that is already closing again. This can unduly heat the heads or rods, but also the warp threads. Moreover, this forced opening of the shed by the above mentioned gripper elements can produce defect locations in the woven fabric.
It is an object of the invention, in looms and shedding machines with separate drive technology, under the boundary conditions of an at least point-wise synchronous operation,
Point-wise synchronous operation is to be understood to mean that the drive of the loom and the shedding machine is operated synchronously in a predefinable point, weaving cycle for weaving cycle. This point can be different weaving cycle for weaving cycle.
The object is achieved according to the invention in that a control arrangement for the control of the electric motor drive of the loom and for the control of the electric motor drive of the shedding machine comprising at least one additional inertial mass possesses or has suitable computer means, which determines the applicable size or magnitude of the moment of inertia of the inertial mass to be allocated dependent on machine and/or weaving technical data, and in that suitable means are present, which make it possible to arrange or set-up the at least one additional inertial mass in such a manner so that the magnitude of the determined moment of inertia becomes effective in the operating of the shedding machine.
The accompanying single drawing figure schematically illustrates a block diagram of an arrangement for carrying out an example embodiment of the inventive method. The arrangement includes a loom and a shedding machine each respectively connected to a respective electric motor drive, an adjustable and/or exchangeable inertial mass (e.g. flywheel), and a control arrangement including computer means.
Such additional, that is to say not inherent, inertial masses do reduce the dynamics of the shedding machine, yet the solution according to DE 100 53 079 of the applicant provides the possibility to start and to stop the shedding machine more slowly than the loom. Through this achieved degree of freedom, the installation of non-inherent inertial masses becomes possible without or without significant enlargement of the drive unit.
Thus, through a correspondingly large additional or auxiliary inertial mass on the drive shaft, the rotational speed fluctuations of the shedding machine can be kept very small, regardless how strong the motion of the shedding means is. The drive transmission of the shedding machine can be laid out under the prescription of a constant rotational speed of the drive shaft; moreover, the motion course or progression curves of the loom transmission (for reed and grippers) can be optimized for this behavior of the shedding machine, so that the object with respect to weft insertion is achieved. Thereby, a direct drive without additional inertial mass can be fundamentally provided for the loom.
A further improvement of the optimization criteria can be achieved in that an additional or auxiliary inertial mass is fixedly specified for a shedding machine with a certain maximum possible motion of the shedding means. Thus, as an example, in connection with an electronic dobby machine, one can define the band width of no shedding means motion up to and including heald frames or shafts 1 to 6 in a 1:1 binding weave as a “range of weak shedding means motion”. One specifies the size of the additional inertial mass in such a manner so that a prescribed tolerance in the rotational speed oscillation is not exceeded in connection with the strongest shedding means motion (that is to say heald frames or shafts 1 to 6 in 1:1 binding weave). Now, the transmission of the shedding machine can either be laid out or designed according to the principle of the rotational speed constancy, or on the basis of a defined rotational speed oscillation on the drive shaft, which preferably corresponds to the average shedding means motion within the range “range of small shedding means motion”. In the example, this average shedding means motion may correspond approximately to the motion of the heald frames or shafts 1 to 4 in 1:1 binding weave. The characteristic progression curves of the loom transmission (for reed and grippers) are correspondingly adapted or matched (see above).
If one now defines, for example, ranges of medium- or middle-strong and strong shedding means motion, thereby, through installation of corresponding larger inertial masses, one can again achieve the level and the progression of the rotational speed oscillation as for the range of weak shedding means motion. The transmission of the shedding machine once again experiences the operating conditions or relationships for which it has been laid out or designed, similarly the tuning or adaptation with the characteristic progression curves of the loom transmission is again produced in the best possible manner.
The advantages of the use of differently sized inertial masses in comparison to a fixedly or rigidly installed very large initial mass are:
In a simple embodiment of the invention, therefore, the at least one additional inertial mass of a first predetermined fixed size can be exchanged with a different additional inertial mass that is of a second predetermined fixed size.
For avoiding the assembly or installation time necessary for the exchange of the inertial mass, according to the invention an inertial flywheel with a variable or adjustable moment of inertia can be provided, as is the subject matter of the DE Patent Application 101 61 789.5 of the applicant, for example. In that regard, the flywheel consists of a base body that is rotationally fixedly connected with the drive shaft of the shedding machine and at least two partial masses that are radially movable relative to the rotation axis on the base body, whereby the radial position of the partial masses is changeable through operating means, for example during the rotation of the flywheel. In that regard, the operating means can be an integral component of the flywheel and comprise adjusting or actuator means that act directly or indirectly on the partial masses.
In a preferred embodiment of the invention, the moment of inertia of the hereby variable or adjustable additional inertial mass(es) can be changed or adapted between a minimum and a maximum continuously dependent on the operating behavior of the shedding machine.
Suitable computer means can, for example dependent on machine and weaving technical data, automatically determine the applicable size or magnitude of the moment of inertia of the additional inertial mass(es), and represent or indicate this to the operator of the loom, preferably in the display of the loom control. In this regard, especially the following should be mentioned as machine technical data:
Loom
Shedding machine
In this regard, especially the following should be mentioned as weaving technical data:
The adjustment or adjusted setting of the additional inertial mass(es) and/or the exchange of the additional inertial mass(es) and/or the supplementing/reduction of the additional inertial mass(es) in that regard can be carried out manually or can be achieved automatically through suitable means.
The motion profiles of the loom and the shedding machine that are well tuned or adapted already on the side of the transmission due to the additional inertial mass(es) have as a result, that the required control/regulation demand for weaving technical synchronization of both machines is considerably reduced, whereby also the intended nearly energy-constant operation of both machines becomes possible—and therewith in turn current consumption, resistive or dissipative heat losses as well as the loading of the power electronics and motor are held to a low level.
Number | Date | Country | Kind |
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102 06 972 | Feb 2002 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE03/00264 | 1/31/2003 | WO | 00 | 8/20/2004 |
Publishing Document | Publishing Date | Country | Kind |
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WO03/071017 | 8/28/2003 | WO | A |
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20021049 | May 2001 | DE |
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Number | Date | Country | |
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20050178457 A1 | Aug 2005 | US |