The invention refers to a tool module for textile machines, particularly for tufting applications.
Particularly the invention refers to a tool module for fastening at a bar of a textile machine as, for example, a tufting machine or also a warp knitting machine.
The bar of the tufting machine or warp knitting machine is provided with a large number of tools as, for example, grippers, needles, guide needles, knives or the like, that are aggregated by forming groups in modules. Each module comprises a base body in or at which a number of tools is attached. In order to equip the bar with the tools, the modules are connected with the bar.
This principle can be derived from DE 4223642 C2, DE 4411277 A1, U.S. Pat. No. 5,947,942. Thereby, the module bodies are typically provided with form fit structures that simplify a positioning in correct positional arrangement of each module at the bar.
Further, a module with a larger cutout provided in the module body, in which a positioning element can be inserted, is known from DE 19928885 C1. It extends through openings in the module body that are provided with alignment structures in order to come into a correct positional arranged engagement with these openings. The insertion part comprises additional alignment structures that come into contact with forms of the bar that are complementary thereto. A set of different insertion parts provided with different alignment structures allows the adaption to different bar systems.
Further, a tool module is known from DE 10 2012 112 553 B3, the module body of which comprises alignment structures and depressions extending along the alignment structures. They shall serve an improved positioning of the modules at the bar.
A large portion of the drive power provided to the tools of a textile machine is converted into heat due to friction, wherein a relatively large heat proportion is created at the tools. This can lead to a longitudinal extension of the bar that can be disadvantageous for the operation of the machine, particularly in tufting machines and warp knitting machines. Additionally, a remarkable increase of the dynamic loads that particularly act on the bearings and drives as well as an increased bending stress of the bar occurs with increased operation speed, that is oscillation frequency of the bar.
It is the object of the invention to provide a concept with which the operation speed of a textile machine can be increased the tools of which are held in modules.
This object is solved with a tool module according to claim 1:
The inventive tool module comprises a module body with a contact surface on or at which an alignment structure for positioning at a bar is provided. The alignment structure comprises at least one projection and/or at least one depression that can come in engagement with a respective complementary form of the bar in order to allow a definite positioning of the tool module at the bar. In the simplest case, the alignment structure is formed by a continuous or interrupted ridge that is arranged at the border of a contact surface with which the module body comes into contact with the bar. Then, the ridge comprises a contact surface that lies on a further surface of the bar. The ridge can be arranged between the contact surface and a narrow side of the module body.
According to the invention, the tool module is penetrated by at least one opening that does not correspond with the fastening opening and thus has neither a fastening function nor a positioning function (form fit function). The opening has preferably a closed border, but can also be an open-jaw-like opening that is open at the laterally narrow sides of the module. The opening that penetrates the contact surface and that is open at the side facing away from the contact surface and separated from the fastening opening reduces the weight of the tool module, reduces the heat transfer surface from the module to the bar and thus reduces also the heat increase of the bar. Additionally, the at least one opening can improve the cooling of the module during the operation of the machine. The heat that is created due to friction of the tools at a backing of another textile or at a thread is received by the module body and dissipated to the environment as well as in now reduced manner to the machine bar. An excessive heat introduction in the bar and thus a length extension thereof during the operation is avoided. In the ideal case, the heat is dissipated in the ambient air. Due to the oscillating operation of a bar with the tools attached thereon convection is enforced. The at least one opening separated from the fastening opening creates an additional swirl of the air that is in contact with the module during the operation of the machine which leads to an increased convection and thus an increased heat dissipation.
The module body is preferably manufactured by a molding process, wherein preferably a zinc alloy is used as molding material. The tools, for example tufting needles, grippers, knives or the like are held with a fastening end in this module body that is molded therein. After the curing and cooling of the module body they can have particularly at its position defining surfaces a certain deviation from the straightness (unevenness), for example at the contact surface. Due to forming of at least one additional opening that penetrates the contact surface and the module body straightness fluctuations of the module body are reduced and the error influence of such straightness deviations on the positioning accuracy is reduced. The clamping situation of the tool module in total is thus increased.
The contact surface of the tool module is the surface that faces the bar and is in contact therewith during operation. Preferably the contact surface is configured as a plane, wherein elements that form part of the alignment structure extend away from the contact surface. Such elements can be projections in the form of prismatic, cylinder-shaped or dome-shaped projections that preferably extend parallel to each other away from the contact surface. Corresponding depressions in the bar are typically assigned to these projections. Additionally or alternatively a continuous or superiorly interrupted ridge is part of these projections that is arranged adjoining to a narrow side of the module body. This narrow side is the side that is penetrated by the tool shanks of the textile tools. If the ridge is interrupted it can be reduced to two projections standing at the corners of the module. This leads to a maximum weight reduction while completely preserving or improving the positioning accuracy. If the ridge is the solely present alignment structure, the modules can be laterally adjusted or shifted at the bar for the machine setup.
The above-mentioned, for example cylinder-shaped or otherwise configured projections are preferably arranged at both sides of the fastening opening on a line that is parallel with the narrow side of the module body and thus to the ridge provided there. Due to this separation a third zone is created between a zone of the module body in which the tool shanks are held and another zone that comprises the fastening opening and the projections at the two sides thereof, in which the additional openings for weight reduction, straightness improvement and convection improvement are arranged. Thus, the zone holding the tool shanks and the zone serving for fastening are connected with each other by two, preferably three webs that are orientated parallel to each other at least two of which, preferably three, can have the same cross-section respectively.
Typically, the fastening opening comprises a diameter that substantially corresponds to the diameter of one of the projections. However, this is not obligatory. It is, however, aimed to adapt the diameter of the fastening opening to the fastening means in order not to excessively weaken the fastening section of the module body. If a certain resilience of the module body is desired at all, it can be provided by the two to three webs extending between the fastening section and the tool section.
Further details of advantageous embodiments of the invention are subject of the drawings, the description and the claims. The drawings illustrate an embodiment of the invention. The drawings show:
In
The module body 11 is preferably formed of metal, particularly a zinc alloy, a zinc aluminum alloy or another metal alloy melting at a temperature below 1.000° C. Particularly, the module body 11 can be formed as die-cast body.
The module body 11 hast substantially the form of a flat plate with a narrow side 20, at least one tool, here the tools 12-18, extending away therefrom. Additionally, the module body 11 comprises a substantially flat contact surface 21 that is in contact with a bar for accommodating and positioning the tools 12-18. At the opposite side of the module body 11 a substantially flat or also with additional structures provided backside is formed, that is substantially orientated parallel to the contact surface 21.
Particularly at the contact surface 21 as well as the transition to the narrow side 20 elements are provided that form an alignment structure 22 or that are part thereof. For example two cylinder-shaped projections 23, 24 are part of these elements that preferably extend parallel to each other away from the contact surface 21. The ends of the projection 23, 24 can be provided with an insertion chamfer, a rounded camber or the like. Alternatively, the projections 23, 24 can have a cross-sectional shape deviating from the circular shape as, for example, polygonal shapes or can be configured as rounded domes.
A ridge 26 provided with an interruption 25 can additionally or alternatively form part of the alignment structure 22 that is arranged between the narrow side 20 and the contact surface 21. The ridge 26 can be separated from the contact surface 20 by a groove 27—for this purpose reference is made particular to
As apparent from
The module body 11 thus comprises a fastening section 31 that comprises the projections 23, 24 (if present) as well as the fastening opening 29. Further, the module body 11 comprises a holding section 32 into which the fastening ends of the shanks of the tools 12-18 extend. Between the fastening section 31 and the holding section 32 one, preferably multiple additional openings 33, 34 are provided in the module body 11 as particularly apparent from
The additional opening 33 or 34 respectively comprises preferably a trapezoidal basic shape with rounded corners and overlaps with reference to the axial direction of the tools 12-18 (vertical direction in
The long edge of the trapezoidal-shaped basic structure at the fastening opening facing the projection 23 can be bulged outwardly in an arc-shaped manner. Additionally, the corners are preferably rounded. In doing so, a connection structure is created between the fastening section 31 and the holding section 32 formed by three webs 33, 38, 39 (
The tool module 10 described so far is attached to a bar during operation in that it is brought in the desired position in the alignment structure 22 and fixed in this position. If present projections 23, 24 are inserted in corresponding cutouts of the bar and the rib or ridge 26 as well as the contact surface 21 are brought into contact with the bar. By means of a screw or a suitable corresponding means that extends in or through the fastening opening 29, the tool module is captively held at the bar.
In operation the bar oscillates substantially in axial direction of the tools 12-18 back and forth, wherein the tools 12-18 come into frictional engagement with the respective mostly two-dimensional textile and execute an operation at the same, for example piercing a thread therethrough, form loops or the like. The friction occurring at the tools 12-18 heats them, wherein the heat is introduced to a certain proportion in the module body 11. The reduced contact surface 21 impedes however the transfer of heat to the bar. Concurrently, the openings 33, 34 swirlingly act on the ambient air during fast back and forth movement of the bar and thus support the heat dissipation, particularly from the holding section 32. The webs 37, 38, 39 further reduce the heat transfer from the holding section 32 to the fastening section 31.
It is indicated that the additional openings 33, 34 lead to a weight reduction of the module body 11 such that its material choice can be made independent from the material density. The weight reduction reduces the dynamic stress of the bar and the machine parts guiding it during the oscillating back and forth movement of the bar which in turn allows an increase of the operating speed.
A tool module 10 according to the invention comprises a module body 11 with a contact surface 21 and an alignment structure 22. The contact surface 21 is penetrated by a fastening opening 29 and additionally by at least one, preferably multiple additional openings 33, 34. The area of an additional opening 33 or 34 is larger, preferably remarkably larger, for example at least two times or three times as large as the cross-section area of the fastening opening 29. In doing so, a module body 11 is provided with which an increased operation speed of the textile machine can be achieved.
Number | Date | Country | Kind |
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10 2017 116 043.4 | Jul 2017 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/069266 | 7/16/2018 | WO | 00 |