JP2004150007A - Negative dobby drawing mechanism and loom having the drawing mechanism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a new drawing mechanism more simplified than conventional drawing mechanisms and having an easily adjustable shed. <P>SOLUTION: The drawing mechanism has flexible elements 30-33 for each heald frame 70, the flexible frame is extended between an element operable by a negative dobby 10 and an assembly 60 of a return spring and fixed on the element, an spring assembly 60 and two return levers 40 and 50 each connected with the frame 70. The flexible element 30 is directly connected with a rocking lever of the dobby, the rocking lever has a fixed amplitude and has a double arm swinging lever 14, the swinging lever has a hook 15 selectively cooperated therewith, the hook is selectively cooperated with a reader 20 of the dobby to temporarily lock rocking levers 11 and 11'. The flexible element is adjustably connected with one return lever and, thereby, a space d between the flexible element and a pivot 45 of the return lever is adjustable. <P>COPYRIGHT: (C)2004,JPO

Description

  The present invention relates to a pulling mechanism (return mechanism) for controlling a heald frame of a loom having a depolarized dobby. The present invention further relates to a loom provided with such a pulling mechanism.

In the field of depolarized dobbies, it is known, for example, from US Pat. In this tensioning mechanism, a flexible element such as a cable is secured on the one hand to a return spring assembly or resistor and on the other hand to a member controlled by the dobby. The flexible element is continuously supported by two return levers, each connected to a heald frame. Due to the plurality of heald frames to be driven, a number of flexible elements and associated sets of levers are provided. This known mechanism is relatively complicated when the device for adjusting the shed must be provided in the connection area between the flexible element and the member driven by the dobby. In this case, the above-described member driven by the dobby must be mechanically connected in an adjustable manner to a locking lever driven by the dobby. This complicates and is relatively heavy for structures that are heavily accelerated as the dobby functions. In this type of device, the shed adjusting element is located inside the dobby. Thus, the sheep adjusting element is difficult to access.
European Patent Application Publication No. 0527095

  It is an object of the present invention to overcome the above disadvantages by proposing a new tensioning mechanism that is simplified compared to the state-of-the-art tensioning mechanisms and that can be adjusted easily.

  In order to solve this problem, the present invention is a tensioning mechanism for controlling a heald frame of a loom with a depolarized dobby, for each of which the flexible element is actuated by the dobby. The invention relates to a tensioning mechanism extending between a member and a return spring assembly or register, wherein a flexible element is secured to said member, said assembly and two return levers each connected to a frame. The tensioning mechanism is such that the flexible element is directly connected to the dobby locking lever, the lever has a constant amplitude, and comprises a double-armed rocking lever, the rocking lever comprising a hook, which comprises a hook. Selectively cooperating with the dobby reader to temporarily lock the locking lever, a flexible element is adjustably coupled to one of the return levers so that the flexible element and the return lever The distance between the pivot axes can be changed.

  According to the invention, it is not necessary to provide a shed adjustment device at the level of the dobby. The shed adjuster is thus greatly simplified because it is a simple structure and is offset to the level of one return lever which is more accessible than the dobby element.

According to an advantageous, non-obligatory aspect of the invention, the mechanism includes one or more of the following features.
The lever with constant amplitude is provided with a shoe for supporting and guiding the flexible element.
The return lever, to which the flexible element is adjustably connected, comprises a stirrup element movable relative to the lever and fixed to the flexible element; In this case, the extension preferably extends substantially perpendicular to the direction of the flexible element between the locking lever and the return lever.
The flexible element is formed by a plurality of parts; The portions extend between the locking lever and the first return lever, between the two return levers, and between the second return lever and the return spring assembly, respectively.
A plurality of locking levers pivoted on a common shaft are provided with dobbies; The spacing between the fixing area of the flexible element of each lever and this axis is not the same for all these locking levers. The locking levers can be distributed in at least two groups. In this group, the spacing between the anchoring area of the flexible element and the common axis is the same, and this spacing varies from group to group. In particular, the value of this spacing may increase from the front to the back of the mouth.
The mechanism is supported by a superstructure; The superstructure comprises a beam having a generally U-shaped cross section open upwardly and being disposed substantially horizontally above the heald frame.

  The present invention further relates to a loom provided with the above-mentioned tension mechanism. Such looms are more reliable and less costly than the state of the art looms.

  Next, two embodiments of a tension mechanism (return mechanism) according to the present invention will be exemplarily described with reference to the drawings. With this description, the invention will be more readily understood and other advantages of the invention will become more apparent.

  The loom M shown in FIGS. 1 to 3 includes a depolarized dobby 10. This depolarized dobby has a locking lever 11 which pivots about a common axis 12. In FIG. 1, only one lever 11 is visible in its entirety. The hood 13 of the dobby 10 has been partially cut away so that a part of the second lever 11 'can be seen.

  The lever 11 includes a double-arm swing lever 14. The swing lever supports the hook 15. This hook cooperates with a holding hook 21 controlled by a control unit 22. Elements 21 and 22 belong to the dobby 1 reader 20.

  The other lever 11 'and its equivalent are likewise provided with a double-arm rocking lever. The swing lever has a hook that cooperates with the reading device 20.

As indicated by the double arrow F _1, lever 11 and its equivalents are pivoted about the shaft 12 at a constant rocking stroke (amplitude). The lever 11 and its equivalent can be selectively retained near the dead center of its stroke by cooperating with the hooks 15,21.

  A flexible cable 30 is connected to each lever 11 and its equivalent, as shown for levers 11 'in FIG. This cable extends from each locking lever 11 or 11 'towards the first return lever 40, is fixed to this return lever, and extends from the first return lever towards the second return lever 50, and likewise It is fixed to the second return lever. The cable 30 extends from this second return lever 50 toward the assembly or register 60. This assembly includes a spring 61 for resiliently returning the levers 11, 40, 50 to a predetermined position. The trajectory of the cable 30 is straight between the levers 11 and 40, between the levers 40 and 50 and between the lever 50 and the assembly 60. Thus, there is no need to provide a return pulley on the track of the cable 30 other than the levers 40 and 50.

  Each lever 40, 50 is connected to the frame 70 by two connecting rods 41, 42, 51, 52, respectively. This frame comprises a heald 71, some of which are visible in the figure.

  The cable 30 actually extends between a plurality of parts, a first part 31 extending between the levers 11 and 40, a second part 32 extending between the levers 40 and 50, and between the lever 50 and the spring assembly 60. It is formed by the third portion 33.

  The parts 31 to 33 together form a flexible element. That is, it forms an element 30 that is continuously supported on levers 40 and 50 and extends between lever 11 and assembly 60.

  Portion 31 has a loop 312 at its first end 311. This loop cooperates with a hook 112 provided on each lever 11 and its equivalent. Each of these levers 11 and their equivalents has a shoe 111 made of elastomer or other material to support and guide the cable 30.

  Each shoe 111 has a substantially sector shape centered on the shaft 12. In a variant, the shoes 111 may have a center on an intermediate axis between each shoe 111 and the shaft 12.

  Portion 31 is connected to two plates 314 at opposite ends 313 thereof. This plate is pivotally connected to the stirrup element 315 slidably on the projection 43. This protrusion extends from the main part 44 of the lever 40 in the direction AA 'substantially perpendicular to the direction BB' of the cable 30 between the levers 11 and 40 and to the rotation axis 45 of the lever 40. Extending.

  43a and 43b indicate edges on both sides of the protruding portion 43. The edges are parallel to each other and to the direction AA '.

The _double arrow F2 indicates that the stirrup element 315 is slidable on the protrusion 43.

Stirrup element 315 is provided with a screw 316 for applying a force F ₃ that stuck the stirrup element 315 along the protruding part 43.

  By sliding the stirrup element 315 along the protrusion 43, the distance d between the part 31 of the element 30 and the shaft 45 can be changed.

This allows the point of action of the traction force F ₄ applied to the lever 40 by the portion 31 of the cable 30 to be slightly offset with respect to the shaft 45. This makes it possible to adjust the stroke of the frame 70 controlled by the levers 40, 50, ie to adjust the shed obtained by the loom M.

  The portion 32 has its ends 321 and 322 connected to the levers 40 and 50, respectively. Portion 33 is connected at its respective ends 331, 332 to lever 50 and assembly 60. This assembly is located between levers 40 and 50.

The main part 44 of the lever 40 is made of steel and is integral with the projection 43. Component 44 includes a sector 46 to support portion 32 of cable 30 near its end 321. This sector can be made of synthetic material. The component 44 further comprises a hook 47 for fixing the part 32. The sector 46 defines an area Z _{4 of the} lever 40. From this region, the portion 32 of the element 30 extends to the region Z ₅ of the lever 50. The region Z _5, the end portion 322 of this portion is supported. Meanwhile region Z ₄ is disposed between the shaft 45 and the frame 70, i.e. below the axis, the region Z ₅ is arranged on the opposite side to the frame 70 with respect to the upper, i.e. the axis 55 of the shaft 45.

Lever 50 defines a second region Z _'5 located between the shaft 55 and the frame 70. From this area, the part 33 extends substantially perpendicular to the reciprocating direction Z-Z 'of the frame 70.

Due to the distribution arrangement of the zones Z ₄ , Z ₅ , Z ′ ₅ , the parts 32, 33 forming the cable 30 do not intersect the connecting rods 41, 51. Thereby, the connecting rod can have a width that gives good mechanical properties.

Lever 50 is actually formed by the region Z _5, Z _'5 2 two scallops of synthetic material defining a 56, 56', a metal insert is disposed between the regions.

  The levers 40, 50 are considered "pulley levers" in view of their shape.

  In view of the foregoing, adjustment of the shed formed by each frame 70 is achieved by moving the stirrup element 315 on the extension (projection) 43. The stirrup element and extension are easily accessible above the heald frame.

  Once the desired adjustment has been achieved, i.e., the desired distance d between the cable 30 and the shaft 45, the stirrup element 315 is immobilized on the projection 43 by a screw 316. To facilitate this adjustment, the protrusion 43 may be provided with a scale (not shown).

  The adjustment of the shed may vary from frame to frame.

  To prevent the protrusion 43 provided on each lever 40 from becoming too long, the lever 11 and its equivalent may have two sizes (size groups). That is, each shoe 111 may have a shape in which the turning radius R of each shoe 111 around the axis 12 is different between the two lever groups. In the example shown, the levers are distributed and arranged in two groups. In other words, the shoe 111 is distributed and arranged to a lever of the type of the lever 11 having a relatively small turning radius R and a lever of a type of the lever 11 'having a large turning radius R'.

  In practice, a lever with a large radius R 'is located at the rear of the shed, i.e. on the loom beam side.

  The above elements are supported by a beam 80 whose main axis XX 'is horizontal. This beam is arranged above the loom frame 70 and has an opening 84 for the passage of the connecting rods 41,51.

  In particular, as shown in FIG. 2, the beam has a U-shape whose cross section is open substantially upwards, the pivot 45 of the return lever 40 being supported by the two lateral webs 81, 82 of the beam. I have. Similarly, the pivot 55 of the lever 50 is supported by the lateral web of the beam 80.

  A rod 62 extends between one end 83 of the beam 80 and the assembly 60 and includes a system 63 for adjusting the tension of the spring 61. This system can adjust the elastic force generated by each flexible cable 30 by the assembly 60.

In the second embodiment of the invention shown in FIG. 4, elements similar to those of the first embodiment have the same reference numerals. The second embodiment in substantially the second portion 32 of the flexible cable 30, the first return region Z ₄ of the lever 40 similar to the region of the first embodiment, the second return that extends between the second region Z ₅ formed by the fan-shaped portion 56 of the lever 50 are different. The region Z ₅ is located between the pivot axis 55 and the frame 70 of the lever 50. Thereby, the portion 32 is substantially perpendicular to the reciprocating direction Z-Z 'of the frame 70.

Further, a spring assembly 60 disposed between the levers 40 and 50 is connected to the lever 50 by a portion 33. This part ₅ and the frame 70 'region Z formed by' the opposite of the second sector 56 of arranged on the side lever 50 about the axis 55, extending between the spring assembly. Portion 33 is substantially perpendicular to direction Z 'between elements 50 and 60.

  As described above, the stirrup element 315 secured to the end 313 of the part 31 of the element 30 can slide along the protrusion 43 formed by the lever 40. As a result, the distance d between the pivot shaft 45 of the lever and the cable 30 can be changed.

Fig. 3 schematically shows a loom according to the invention, with the support beam part and the dobby hood cut away. It is a perspective view of the part of the loom of FIG. FIG. 3 is an enlarged detail view of section III of FIG. 1 with a rod for adjusting the position of the spring assembly omitted for clarity; FIG. 4 is a view similar to FIG. 1 of a mechanism according to a second embodiment of the present invention.

Explanation of reference numerals

DESCRIPTION OF SYMBOLS 10 Dobby 11, 11 'Locking lever 12 Common shaft 14 Swing lever 15 Hook 20 Reader 30-33 Flexible element 40, 50 Return lever 45 Pivot shaft 55 Pivot shaft 60 Return spring assembly 61 Return spring 70 Frame 80 Beam 111 shoe 315 stirrup element

Claims (12)

A tensioning mechanism for controlling a heald frame of a loom with a depolarized dobby, wherein for each heald frame a flexible element is moved between a member actuated by said dobby and a return spring assembly or register. The tensioning mechanism, wherein the flexible elements (30-33) extend and are secured to the member, the assembly, and two return levers, each coupled to the frame. Directly connected to the locking lever (11, 11 ') of the dobby (10), said lever having a constant amplitude and comprising a double-armed rocking lever (14), which rocks the hook (15). Wherein the hook selectively cooperates with the dobby reader (20) to temporarily deactivate the locking lever, and a flexible element connects one of the return levers (40, 50). Adjustably (F ₂₎ coupled to the (40), tensile mechanism, characterized in that the result the spacing between said flexible element return lever pivot axis (45) (d) can be changed .   2. The tension according to claim 1, wherein said lever having a constant amplitude is provided with a shoe for guiding said flexible element. mechanism. It said flexible element (30) adjustably linked return lever (40) is a movable relative to the lever (F ₂₎ and the flexible element anchored stirrups elements (315 3. The tension mechanism according to claim 1, wherein the tension mechanism comprises:   The extension (43) is substantially perpendicular to the direction (B-B ') of the flexible element (30) between the locking lever (11, 11') and the return lever (40). 4. The tensioning mechanism according to claim 3, wherein the tensioning mechanism extends along AA ').   The flexible element (30) is formed by a plurality of parts (31, 32, 33), each of which is between the locking lever (11, 11 ') and the first return lever (40), 5. The method as claimed in claim 1, wherein the first and second return levers extend between a second return lever and a return spring assembly. The pulling mechanism according to one.   It comprises a plurality of locking levers (11, 11 ') pivotally mounted on a common axis (12), all locking levers having an anchoring area (111) of the flexible element (30) in each locking lever and 6. The tensioning mechanism according to claim 1, wherein the distances (R, R ') from the shaft are not the same.   The locking levers (11, 11 ') are distributed in at least two groups, in which the spacing (R, R) between the fastening area of the flexible element (30) and the common axis (12). 7. The pulling mechanism according to claim 6, wherein R ') are the same, and the distance is different for each group.   8. The tensioning mechanism according to claim 6, wherein the value of the distance (R, R ') increases from the front to the rear of the shed.   A tensioning mechanism is supported by a superstructure comprising a beam (80), which beam has a generally U-shaped cross section open upwards, and a substantially horizontal direction (XX) above said frame (70). The tensioning mechanism according to any one of claims 1 to 8, characterized in that the tensioning mechanism is arranged in (1). Said flexible element (30 to 33) is a region of the first return lever located between the pivot axis of the substantially first lever (45) and the frame (70) (40) (Z ₄₎ When, extending between the region (Z ₅₎ of said second return lever (50) and said frame with respect to the second lever (50) of the pivot (55) located on the opposite side of said assembly (60 ) Is disposed substantially between said levers (40, 50), said flexible element being substantially between the pivot (55) of said second lever (50) and said frame (70). 6. The device according to claim ₅ , wherein the second lever extends between a region of the second lever located therethrough and the assembly which is substantially perpendicular to the direction of reciprocation of the frame. The tension mechanism according to any one of claims 1 to 9. Said flexible element (30 to 33) is a region of the first return lever located between the longitudinal axis of substantially the first lever (45) and the frame (70) (40) (Z ₄₎ When, extending between a region of the second return lever located between the frame and the pivot axis substantially said second lever (50) (55) (50 ) (Z 5), said assembly (60 ) Is disposed substantially between said levers (40, 50), said flexible element being substantially opposite to said frame (70) with respect to the pivot (55) of said second lever (50). , Extending between the area of the second lever (Z ′ ₅ ) located on the side of the frame and the assembly substantially perpendicular to the direction of reciprocation of the frame (ZZ ′). The pulling mechanism according to claim 1.   A loom (M) comprising the pulling mechanism (10-80) according to any one of the preceding claims.

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