CS213350B2 - Cotton's frame - Google Patents

Abstract

The loom with straight rods has a configuration which avoids or attenuates the limitations inherent to the Cotton type loom and which is capable of being developed. This knitting loom with straight bars has a knitting head in which the knitting equipment is mounted on bars (130), pivoted levers (86a, 86b) and connecting rods (146) directly or indirectly connecting together the moving bars (130) and the levers (86a, 86b) for imparting advancement or retraction or up and down movements to the members with the view of forming knitwear. The levers (86a, 86b) for a predominant number of movements of the knitting equipment are located in a longitudinal L-shaped zone. They are connected by connecting rods (146) directly or indirectly to a bar (130) or to respective moving bars in order to form the knitwear, in a zone diagonally opposite the region of the pivots of the levers (86a, 86b), in quadrangular configurations formed by the levers (86a, 86b) and the connecting rods (146). <IMAGE>

Description

The invention relates to column strikes and, in particular, to the actuating mechanisms of their individual working elements.

Since the introduction of the original Cotton invention described in British Patent No. 3,123 of 186.4, column strikes have essentially retained their original solution with minimal variation. In most multi-headed cotter strikes, the compound movement is supplied to the needle bed by upper levers pivotally attached to each end of the needle bed to support the needle bed and ensure its vertical movement, while providing a horizontal support arm rotatable with the needle bed while providing horizontal swinging movement of the needle bed. Movements are induced by cams on a single rotating camshaft. These cams engage levers mounted on the longitudinally oriented shafts of the lever for imparting vertical movement and a lever for imparting horizontal movement that imparts movement to the lower linking arm connected to the above-mentioned support arm for the horizontal pivoting movement of the needle bed.

Viewed from the side, the set of levers, support arms and linkage levers has the form of a quadrangle with longitudinal shafts in one upper corner, a needle bed outside the quadrangle at the other upper corner, and cams below the quadrangle. When viewed from the front, the levers, the support arms and the linkage levers are spaced apart from one another such that. they are mounted in different parts of the longitudinal shafts so that one cam can. operate a series of levers. The control mechanisms for the platinum boxes and the ejection combs and other mechanisms added over time were placed on strike on similar longitudinal shafts as described, for example, in U.S. Patent No. 3,397,555.

In the less common single head pan strike described in British Patent Nos. 411 517 and 867 391, the basic needle bed operating mechanism is left unchanged. The longitudinal shafts are grouped closer together and some parts of the added double knitting mechanisms are controlled by separate cams on each side of a single section.

Brdy Patent No. 643,624 shows a common longitudinal shaft for levers and a single camshaft located within the aforementioned quadrangular formation, but does not provide adequate pressing of the needle hooks before the stitches are dropped because the needle bed is pulled into the press by a spring over a quadrangular formation, thereby losing structural rigidity.

The long distance the driving force is at ....... ... ¾¾¾¾¾¾ 'of known strikes transmitted from cams to the lever, to the longitudinal shaft and then the lever and the link arms to the needle bed, reducing the straightness of the needle bed drive, the space saving of the drive train and the ability to work fast. Similar arrangements for transmitting other movements present the same difficulties. The strike also occupies a relatively large floor area.

In order to combine different driving elements in known strikes, it is usually necessary to supply them with a different shape, length or size, so that the number of elements to be stored for operating the strikes is very high. This implies difficulties in incorporating other elements, not only because of their quantity, but also for production costs, so that known strikes have. limited options for further improvement by increasing the working speed, or. that it is possible to perform other acts on the strike, or that the provision of such other acts is facilitated.

In addition, with known strikes, the working head itself is not well designed in terms of internal space saving and quick working. At higher speeds, hobby noise and rocker wear increases, and the ejection comb that is clamped between the needle bed and the platinum bed tends to bend at high speeds, or requires additional reinforcement to be such - Avoid bending. Even if working at high speeds is possible, the cam drive mechanism causes the rollers to pop out at the tops of the cams, thereby interfering with the precise control of the individual movements.

The retracting mechanism typically employs rigid rod friction boxes and drive rails - a hobby that occupies a large space and - not suited - to work at high speeds. Endless belt mechanisms, developed as an alternative, lead to malfunctions and place demands on the space at the back of the work head.

Taken together - the disadvantages of known coton bets, it is therefore obvious that the known bets have relatively limited possibilities for further technical development and improvement, - since the various mechanisms to which the variations would relate each other in terms of space requirements . The danger of collisions between the individual control strikes is then an obstacle to their further technical development, since the shaping and positioning of additional mechanisms in the limited space of a traditionally arranged strike leads to a limitation of the working speed of the machine, thereby reducing productivity. . Increasing the space - in which the actuated controls move - could keep the machine's working speed at its original level, but it adds to the floor space of the production hall and, of course, makes the machine more expensive.

An obstacle to the development of coton strikes according to the prior art is that the adaptation of strikes to other conditions leads to the necessity of a complicated rebuilding of a number of individual components and their re-arrangement. In recent decades, therefore, the development of koton strikes has continued only at a very slow pace, and the subject of development has focused only on the use of new patterning devices with little productivity improvements. Repairs of machines according to the changing fashion then always brought difficulties because, in the traditional solution of the coton strikes, the adjustment of the control mechanisms always led to - Greater complexity and higher specialization of the individual parts. The vulnerability of existing machines to world-wide fluctuations was therefore very high.

The object of the invention is to break this vicious circle in the development of the coton strikes resulting from the fact that all new technical solutions are essentially based on the traditional arrangement according to the original Cotton patent. Its goal is to reorganize the strikes so that the individual parts can be standardized, interchangeable, easy to inspect, all without reducing the speed of knitting and increasing space requirements.

This object is achieved by a work head cotter strike whose needles are housed in a rod-shaped bed, - a pendulum mounted on horizontal displacement levers and vertical displacement levers, which are themselves carried by rotatably mounted operating levers, and a platinum box which is also pivotably mounted on horizontal and vertical displacement levers, also supported by rotatably mounted operating levers, all of these operating levers being actuated by rotary cams for oscillating motion, and further provided with ejection sinkers mounted in a corresponding seat and retractable sinkers mounted in a fixed A bed mounted on a main beam for interacting with a platinum box, wherein according to the invention the control levers for the needle bed carrier and the platinum box are arranged in a longitudinal L-shaped cross-section, It comprises the packaging spaces of the oscillating movable control levers, namely a vertical arm in which the control levers for the first movement component of the needle bed carrier and the platinum box lie, and a horizontal arm in which the control levers for the second movement component of the needle bed carrier lie. and a platinum box, wherein the L-shaped cross-section is a projection of the central region of rotation of the entire assembly and the slide. - levers for - the first movement component of the carrier - the needle bed and the platinum box and the shift levers for the second movement component of the carrier. the needle bed and the platinum box extend from the ends of the corresponding actuating levers of the vertical arm and the horizontal arm to a knitting region which lies diagonally opposite the central region and in which. are attached to the needle bed carrier and the platinum box, wherein the lob packet for the oscillating movable shifting levers for the first movement component forms a horizontal arm of the second L-shaped cross-sectional formation and the shovel position of the oscillating movable shifting levers for the second movement component forming a vertical leg of a second L-shaped cross-section having a vertex in the knitting region, and the two L-shaped cross-sections form together a quadrangular formation with sides formed by the arms, and a central region and region forming two opposing vertices of the quadrangle.

According to a preferred embodiment of the invention, the shifting levers consist of rods rotatably connected at one end to a corresponding actuating lever, and at the other end to a corresponding working element of the knitting machine, i.e. a needle bed carrier or a platinum box.

Preferably, in the quadrangular cross-sectional design of the lever assembly, a main beam corresponding to the knitting head lies on the junction of the central region and the knitting region.

According to a further feature of the invention, in the knitting area on its inner side and diagonally opposite the center of the pivot region, a shaft is provided for transmitting movement to the ejector bed, rotatably mounted on the main beam and carrying rigidly coupled levers. and the bed is provided with a displacement lever for the first movement component, one end of which is connected to the shaft of the ejection sinker and the other end is rotatably connected to the actuation lever for the first movement component, and the displacement lever for the second movement component; one end of which is connected to the sinker bed and the other end. is rotatably coupled to a second lever component, the displacement lever for the first motion component being disposed in the horizontal arm of the second L-shaped cross-sectional formation and the displacement lever for the second motion component in the vertical arm of the displacement member. the second cross-sectional formation, the control lever for the first movement member lies in the vertical arm of the first L-shaped cross-sectional formation and the second lever for the second movement member lies in the horizontal arm of this first cross-sectional formation, and the two control levers are mounted on a common shaft area of rotation. The shifting lever for the first movement component may be coupled to the shaft. by means of a clutch rotatably connected to the shifting lever and fixedly connected to the shaft, and the shifting lever for the second movement component is rigidly connected directly to the ejector bed.

According to a further feature of the invention, the control levers for the movement components of the pivoted knitting elements are supported by rollers constituting the sensors of the control cams supported by the corresponding camshafts, the camshafts being located outside the rectangular configuration defined by the arms of both L-shaped cross-sections. they are preferably each one arm of the articulated lever, the other arm extending outwardly from the quadrangular formation to the cam of the corresponding camshaft, by which it contacts its sensor located at the same distance from the axis of rotation of the articulated lever as the first arm forming the control lever.

The quadrangular formations comprising each one knitting head are preferably arranged parallel and symmetrical. juxtaposed, being positioned between the vertical legs of the first L-shaped cross-sectional formation of the two adjacent quadrilaterals. a common camshaft for actuating the control levers lying in both vertical arms.

Compared to the prior art, the so-called cantilever strike is characterized by a completely different arrangement of the control mechanisms whose individual lever arms lie in line with one another in longitudinal packaging spaces which form the arms of the L-shaped longitudinal spatial formation. control levers stored. on a common shaft. The control levers are thus arranged next to each other and the lever quadrons defined by them are arranged transversely to the axis of the L-shaped longitudinal formation so that even at high stocking densities of these control and shifting levers, the levers cannot collide with each other. The arrangement of the levers also corresponds to the arrangement of other operating mechanisms, namely the control shafts and their cams, which can be arranged side by side with a high density without the risk of collision. This arrangement offers three significant advantages over the prior art. -o-new concept of penetrating progress.

A first advantage is that the arrangement of the levers in the transverse and parallel quadrangular formations makes it possible to incorporate other elements without the risk of collision of the individual control mechanisms. Therefore, strike variations are not detrimental to the machine's working speed, which can remain high and thus maintain high equipment productivity.

A second advantage of the coton strike according to the invention is that the new arrangement is very space-saving and offers room for variation and development of such a conceived solution without the need to increase the floor area or enclosure space and hence the cost of the strike.

Finally, the third advantage results from the very nature of the arrangement of the quadrangular lever assemblies side by side with a common central pivot region, and from the method of controlling crank levers from the camshafts.

Such lever elements can be standardized very easily, so that the same components can be used for different operations and for controlling different machine elements. Thus, for the conversion of a machine that is substantially simplified in this way, the manufacturer can only store a limited number of parts, further reducing investment costs and simplifying the use of the strike. By concentrating the pivoting range of the lever assemblies on a common axis, the need to use numerous longitudinal shafts is avoided, as is the case with traditional column strike solutions, thereby further simplifying the device and reducing its cost.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of the arrangement of the individual packaging spaces of the elements of the apparatus; FIG. 2 shows a diagram of the arrangement of the control levers, shifting levers and working elements; FIG. 3 is a perspective view of a strike according to the invention with two symmetrical working heads showing the operating mechanism for the needle beds. Fig. 4 is a longitudinal cross-sectional view of the strike of Figs. 2 and 3 showing in detail the arrangement of the main controls; Fig. 5 a detail of the working head showing the attachment of the shifting levers to the needle bed carrier, platinum box and sinker bed; 6 cross section of the strike. according to the invention, on an enlarged scale, showing the shape and arrangement of articulated levers, one arm of which constitutes one control lever, as well as the arrangement of cam shafts for controlling the oscillating movements of the control levers; Fig. 8 is a plan view of the end region of the strike showing the arrangement of shafts for receiving the control levers and the main beams of the working heads; Fig. 9 is a front view of the end sidewall. Fig. 10 is a cross-sectional view of the cam assembly, Fig. 12 is a longitudinal cross-section of the cam assembly of Fig. 11, Fig. 13 a view of an articulated lever arm; 14 is a view of the same arm as in FIG. 13, but in a direction perpendicular to the control shafts and the main beams.

As can be seen from the drawings, and in particular from FIG. 5, each working head has a needle bed carrier 1 with which the needle retaining plate 3 interacts. The needle bed carrier 1 is provided at its upper part with a reinforcing flange 4 extending away from the needle The needle carrier 2 is supported at both ends on the mounting brackets 5 lying under the reinforcing flange 4 and is attached to them by screws 6. The brackets 5 are brought in an intermediate position to the stiff sliding levers 7 for vertical movement of the needle beds 2, as will be explained below. The shifting levers 7 are limited in their movement by limiting stops 8 mounted on the main beam 9 of the working head. These limit stops 8 define the position of the needle bed carrier 1 and thus indirectly prevent the side levers from moving sideways so that they only move horizontally across the strike a in the vertical direction.

The shifting levers 7 are articulated at their upper part with other shifting levers 1 which serve, as will be explained below, to ensure horizontal movement of the needle bed 2. The shifting levers 18 extend over the main beam 9.

Further, as shown in FIG. 5, each working head is provided with a sinker box 11 with a bar 12 for engaging the sinkers. The platinum box 11 is carried by sliding levers. 13, which serves to induce its horizontal movement, as will be explained below. The sliding levers 13 of the platinum box 11 are located at its ends and in intermediate positions and are non-rotatable relative to the platinum box. The platinum box 11 is further provided with sliding levers 14 intended to cause its vertical movement, as will be explained below. These shifting levers 14 are located only at the ends of the platinum box 11, and extend through slots 36 in the main beam 9. The guide 12 of the platinum box 11 is provided with a cutout which allows the sliding levers 18 controlling the horizontal to be crossed. movement of the needle bed 2. This allows the operation of both work parts of the head to strike without collisions. The platinum box 11 operates in the usual manner and controls the retractable and equalizing sinkers.

FIG. 5 further illustrates a working head ejection device comprising a ejector bed 15, a ejector sink 16 and a shaft 17 extending along the rear side of the bed 15 and connected thereto at a plurality of locations with short levers 18 spaced therebetween. they are rotatably mounted on the brackets of the bed 15 of the ejector sinkers 16 and on the levers 19 fixedly connected to the shaft 17, which is rotatably mounted on the main beam 9. This provides a pivotal bearing of the bed 15 of the sinkers 16 for control by vertical and horizontal movements, as explained below.

The bed 15 of the ejector sinker 16 is supported from below between its ends by the shifting levers 20 for causing horizontal movement of the bed 15. As with the carrier 1 and the platinum box 11, the bed 213350 ko 15 is also provided with a shifting lever 21 for dispensing its vertical movement, which is schematically indicated in the upper right edge of FIG. 6, and which is best seen in FIG. 1, the content of which will be explained in more detail below. As can be seen from the figure, the shifting lever 21 is connected indirectly to the seat 15 by means of a coupling 30 fixedly connected to the shaft 17.

The bed 15 of the ejection sinker 15 is erected flat in the vertical direction and is therefore not susceptible to deformation due to vertical movements. The levers 18, which are secured against longitudinal movement with respect to the bed 15 by their connection to the levers 19, firmly connect the shaft 17 to the bed 15 of the ejection sinkers 16. Since the shaft 17 is supported in bearings on the main beam 9, it holds the bed 15 of the ejectors against deformation. as a result of horizontal movements.

FIG. 1 shows a method of operating the aforementioned pairs of shifting levers, namely the shifting levers 10, 13 and 21 for the first movement component, in this case horizontal, of the needle bed carrier 2, the platinum box 11 and the ejector bed 16; of the shifting levers 7, 14 and 20 for the second movement component, in this case vertical, of the platinum box carrier 11 and of the bed 15. As can be seen from the figure, each shifting lever 10, 13, 21 and 7, 14, 20 a lever providing transmission of the operating mechanism. All these control levers are rotatably mounted on a common shaft 23, and are articulated to a corresponding displacement lever. The shift lever 10 for the first movement component of the needle bed carrier 1 is thus associated with the control lever 24 and the shift lever 7 for the second movement component of the carrier 1 is associated with the control lever 25. The shift lever 13 for the first movement component of the platinum box 11 is articulated to the control The shifting levers 20 and 21 of the bed 15 of the ejector sinker 15 are then coupled to the control lever 28 for the first movement component, and the control lever 29 for the second movement component. folder. The shifting levers and control levers of each of the three working elements of the knitting strike, i.e. the needle bed carrier 2, the platinum box 11, and the ejection sinker bed 16, thus form a transverse projection to the plane 23 perpendicular to the shaft 23. the apex always lies on the shaft 23, the second opposite apex on the respective working head of the knitting head, and the intermediate apexes form the points of articulation of the respective shift lever to the control lever. This arrangement constitutes a major feature of the invention.

In Fig. 2, the arrangement according to Fig. 1 is shown again, but not in the form of individual levers, but by means of the packaging spaces of their positions. As can be seen from the figure, the control levers 26, 24 and 29 for the first movement component and the control levers 27, 25 and 28 for the second movement component are arranged in a longitudinal L-shaped cross section whose arms Ai A2 forms the envelope of their oscillating positions. The control levers 24, 26 and 29 for the first movement component thus lie in the vertical arm A 1, while the control levers 25, 27 and 29 for the second movement component lie in the horizontal arm A2. The apex of the L-shaped cross-section is the projection of the central rotation region P of the entire shaft assembly 23.

The shifting levers 10, 13, 21 for the first movement component, and the shifting levers 7, 14, and 20 for the second movement component, which extend from the ends of the corresponding actuating levers, are concentrated into packaging spaces defining the remaining two arms Bi, B2 of the quadrangular formation. formed by the arms A1, A2, Bi, B2. The arms B 1 and B 2 extend from the ends of the corresponding control arms 24, 26, 29 of the vertical arm A 1 and the control arms 25, 27, 28 of the horizontal arm to the knitting area H which lies diagonally opposite the central area P. in this case, it lies within said quadrangle in the immediate vicinity of the vertex forming the knitting region H, at the junction of the central region P and the knitting region H of the L-shaped cross-sectional formation.

As schematically indicated in Fig. 1 and as is better seen in Fig. 3, the control levers 24, 26, 29; 25, 27, 28 each comprising a knuckle arm 31a. a member 80 whose second arm 31b extends outwardly from the aforementioned quadrangular cross-sectional formation to the cam 32 of the corresponding camshaft 33, 34. Each arm of the cranked lever member 80 is provided with a corresponding pulley sensor 35a, 35b following the cam contour the camshaft. As can be seen from FIG. 3, the rotation of the cams 32 around the shaft 33 and 34 by successively engaging the cam contour into the free end sensors 35a, 35b of the corresponding control lever 24, 25 is transmitted by successive shifting levers. 10 and 7 for the respective working element of the knitting head, in this case the needle bed carrier 2. For this purpose, the sensors 35a, 35b are located at the same distance from the pivot axis of the knuckle which lies on the shaft 23 in the central region P. . Thus, one sensor mediates a control movement in one direction, while the other mediates the return of the knuckle member 80 to its initial position.

This arrangement makes it possible to achieve a space-saving solution in that the above-described quadrangular formations, each comprising a knitting head, are arranged parallel and symmetrically side by side. An example of such a solution is shown in FIGS. 3 and 6. Between the vertical legs Ai of the first L-shaped cross section of the two adjacent quadrilaterals there is a common camshaft 33 for operating the control levers located in both vertical legs. The cam 32 on the common camshaft 33 of the two associated knitting heads thus gradually engages two sensors 35a and two sensors 35b while rotating, while in the path of the cams 32 on separate camshafts 34 there are one sensor 35a and one sensor 35b each.

2 and 3, it is evident that the individual control and sliding levers can be arranged side by side without the risk of collisions with each other and that the same components can be used for levers of different functional purpose. In particular, it can be seen from the figures that it is possible to standardize the actuating levers as angled lever members 89 with the aforesaid first arm 31a and second arm 31b for accommodating corresponding cam sensors 35a, 35b.

The basic operating and supporting element of each working head of the knitting head, ie the carrier 1 of the needle bed 2, the platinum box 11, and the ejector bed 15, are two quadrangular lever formations. As needed, with respect. However, it is also possible to place intermediate controls or intermediate supports along their length. For example, the needle bed carrier 2 can be supported in the meantime by other control levers 25 and auxiliary shifting levers 7a. Similarly, other control levers 28 and shifting levers 20 may be used along the length of the bed 15 of the ejector 16. The insertion of additional levers 19 and levers 18 along the length of the shaft 17 and a bed for transferring the first movement component of the ejector bed 15 has been described above. Similarly, it is expedient to multiply the number of control levers 26 for the horizontal movement of the platinum box 11 as well as the corresponding sliding levers 13. On the other hand, it is not necessary to use more than two sliding levers 14 and control levers 27 for vertical movement of the platinum box. and control levers 24 for horizontal movement of the needle bed carrier 1.

To summarize, the above data can be gathered in the following table.

Table I

Movement control lever container (arm) sliding lever cover, intermediate, intermediate (shoulder·) podp. carrier 1 25 A2 7 B2 yes, more levers - vertically 25 and 7a carrier 1 24 Ai 10 Bi No —- · horizontal. platinum. 27 Mar: A2 14 B2 No Boxes 11 - vertically platinum. 26 Ai 13 Bi yes, more levers Boxes 11 26 and 13 - horizontal. bed · 15 28 Az 20 May B2 yes, more levers - vertically 28 and 20 bed 15 29 Ai 21 Bi yes, the system of levers - horizontal. 19 and lever 18

on shaft 17

After describing the idea of the invention, demonstrated by way of example, it is still possible to notice other advantageous features of the column strike according to the invention which result from the described new arrangement of its structural elements.

As can be seen from FIGS. 7, 8, and 9, the carcass strike carcass according to the invention has two end plates 37 and intermediate side plates 38 which are connected to each other at the top by a pair of the above main beams 9 and at the bottom by a pair of lower beams 39. a further intermediate beam can be inserted in the lower beams 39. Further, two symmetrically arranged shafts 23 are arranged between the end plates 37 for receiving the control levers of each working head. The main beams 9 each carry one working head, as explained in more detail in the introduction to the exemplary embodiment.

; As can be seen from FIGS. 6 and 9, a control motor 40 driving the input gear 41 of the planetary gear train is located inside one of the end plates 37. With this input gear 41, a central gear 42 mounted on a main shaft 43 engages bearings 44 on the sidewalls 37 and 38. This central gear 42 is further engaged with an upper planetary gear 45 mounted on the upper camshaft 33, which is common to both working heads, as explained above.

The camshaft 33 is also supported by bearings 44 on sidewalls 37 and 38. Furthermore, the sun gear 42 engages a first lower planetary gear 46 mounted on one of the two symmetrically arranged cam shafts 34, which are also supported by bearings 44 on the sidewalls. Finally, it engages an intermediate gear 47 mounted on a short cantilever shaft 48, the intermediate gear 47 engaging another lower planetary gear 46. This second lower planetary gear 46 is disposed similarly to the previous gear. 46, but rotates in the opposite direction.

The cam shafts 33 and 34 may be simultaneously displaced in the longitudinal direction to facilitate the displacement of the individual cam assemblies 49 to different engagement positions with respective crank arms 31a, 31b. The main shaft 43 is connected via a clutch 50 and the reduction gears 51a and 51b, as can be seen in FIG. 10, to a retracting shaft 52 with half-circulating speed. The retracting shaft 52 is driven by a gear 53a that engages the gear 53b on the retracting cam shaft 54. This shaft is mounted on an axial extension of the main shaft 43 and delivers half-speed to the retracting cam 55. A leather belt is mounted around the projection of the gear 53a to act as a brake on the retracting cam 55 prior to disengaging the clutch by means of a mechanism (not shown). The half-speed shaft 52 serves to drive the retraction mechanism.

The described actuators serve to control the knitting and retracting mechanism for the working heads on each of the two main beams 9. The main shaft 43 serves to rotate the camshafts 33 and 34 at the same speed as the main shaft 43 rotates. 34 serves to move the control and shifting levers in the arms A1, A2, Bi, Bz, as already explained in detail. The main shaft 43 also serves to rotate the other cam actuating the retraction mechanism by means of the half-speed retraction shaft 52.

As already mentioned, the cams for operating the individual movable working head elements are arranged on the cam shafts 33 and 34 in the assemblies 49. The cam assemblies 49 on the common shaft 33 are arranged in a double arrangement, one for each working head. Each assembly 49 is mounted on a hub, as shown in Figs. 11 and 12, consisting of two hub halves 56 attached to each other at one end by bolts 57 passing through the projections in the skirt 58. Each hub half 56 has three radially extending recesses 59 supporting the cam halves 60 connected to each other in a cam assembly 49 lying adjacent to each other and fastened by screws 61 to a further projection of the skirt 58. The cam halves 60 have cut-out center portions 62 for weight reduction. The cam assembly 49 thus designed can be easily disassembled without disturbing any adjacent assemblies.

Each cam assembly 49 is associated with a certain knuckle lever member 80, one arm 35a of which forms a respective control lever 26, 24, 29; Each angled lever member 80, as shown in Figs. 13 and 14, has a hub 63 and a pair of arms 31a, 31b. The hub 63 consists of a fastening segment 64 and a supporting segment 65 carrying arms 31a, 31b. Both segments 64 and 65 are connected to each other by bolts 66. The hub 63 is mounted on the shaft 23 with free rotation and is secured against longitudinal movement by the locking rings 67 and the spacers 68. The hub can be supported by an insert 69 keeping it at a distance two adjacent crank levers 25. The spacing of the crank lever members 80 for the various strike working elements may be mediated by sleeve tubes 81 freely slid about the shaft 23.

Both arms 31a, 31b have a thickened portion 70 provided with a recess 71. In this section, corresponding pulley-shaped sensors 35a, 35b are attached to the arms 31a, 31b to follow the contour of the respective cam. The sensor rollers 35a, 35b can be adapted to accurately track the cams by adjusting the position of their bearing plates 72 relative to the corresponding arm 31a, 31b, using screws 73 in the oval holes 75. For standardization, the arms of the knuckle lever 80 can be made or · left-hand adjustment. This is done so that the recess 71 is formed on the left or right side of the arm 31a, 31b and is provided with bearing plates 72 and a pin 74 carrying the pulley 76 of the sensor 35a, 35b as needed, thereby achieving four possible differentiation of the assemblies.

The pin 74 is cut under the insert plate 72 to allow a straight run of the lower edge of the insert. The roller 76, which may include balls in a ball track, has a thin profile and can follow the cam surface even when the cam surfaces are raised on both sides thereof.

As can be seen from FIG. 14, at the other end of the arm 31a opposite to the hub, a respective shifting lever, in this case generally referred to as a shifting lever member 77, is attached to the arm. Mutual rotation of the shifting lever 77 and the arm 31a is ensured by articulating the rotatable about pin 79 with bolt locking.

It is evident from the description of the above details that the arrangement of the sliding and operating levers as well as the knitting head elements of the invention makes it possible to solve the strike controls in a modular manner. It is thus possible to minimize the essential generality of elements and achieve high standardization of working elements for different tasks.

Claims (10)

Column strike with working head, the needles of which are seated in a rod-shaped bed, swingable mounted on horizontal displacement levers and vertical displacement levers, which are themselves carried by rotatably mounted control levers, and an opaque platinum box which is also pivoted on horizontal and vertical displacement levers, also supported by pivotally mounted operating levers, all of which are operated by rotary cams in a reciprocating motion, and further provided with ejectors mounted in a corresponding bed and retractable sinkers mounted in a fixed bed mounted on the main bed A swivel for interacting with a platinum box, characterized in that the operating levers (24, 25 and 26, 27) for the needle bed carrier (1) and the platinum box (11) are arranged in a longitudinal L-shaped cross section. arms (A _b A ₂ forming the packaging spaces of the positions of the oscillatingly movable actuating levers (24, 25 and 26, 27), namely a vertical arm (A _t ) in which the actuating levers (24, 26) for the first movement component of the needle bed carrier (1) lie 2) and a platinum box (11), and a horizontal arm (A2) in which the operating levers (25, 27) for the second movement component of the needle bed carrier (1) and the platinum box (11) lie, the L-shaped cross-section top is a projection of the center rotation region (P) of the entire assembly and of the displacement lever (10, 13) for the first movement component of the needle bed carrier (1) and the platinum box (11) and the displacement lever (7, 14) for the second movement component (1) the needle bed and the platinum box (11) extend from the ends of the corresponding control levers (24, 25 and 26, 27) of the vertical arm (Ai) and horizontal arm (A2) to the knitting area (H) which lies diagonally opposite the central region (P), and in which they are attached a needle bed carrier (2) and a platinum box (11), wherein the envelope of the positions of the oscillating movable shifting levers (10, 13) for the first movement component forms a horizontal arm (Bi) of the second L-shaped cross-sectional formation; the envelope of the positions of the oscillating movable shifting levers (7, 14) for the second movement component form a vertical arm (B2) of a second L-shaped cross-section having a peak in the knitting region (H); a formation with sides formed by arms ((ι, A2, B2, Bi), and a central region (P) and an area (H) forming two opposing vertices of the quadrilateral. Column strike according to claim 1, characterized in that the shifting levers (10, 13; 7, 14) consist of rods rotatably connected to the SUMMARY OF THE INVENTION One end to a corresponding operating lever (24, 26; 25, 27) and the other end to a corresponding working element of the knitting machine, i.e. to the needle bed carrier (2) or to the platinum box (11). A coton strike according to claim 1 or 2, characterized in that, in a quadrangular cross-sectional projection of the lever assembly, a main beam (9) corresponding to the knitting head lies on the junction of the central region (P) and the knitting region (H). A cotter strike according to any one of claims 1 to 3, characterized in that the main beam (9) is provided with end limiting stops (8) of the needle bed carrier (1). 5. A strike according to any one of claims 1 to 4, characterized in that the needle bed carrier (1) is provided in its upper part 0 with a reinforcing flange (4) extending away from the needle bed. 6. A cotter strike according to any one of claims 1 to 5, characterized in that a shaft (17) for transmitting movement to the beds (15) is disposed at the knitting area (H) on the inside thereof and diagonally opposite the center of rotation (P). ) of a ejector, rotatably mounted on a main beam (9) and carrying fixedly coupled levers (19), the other ends of which are articulated to the ejector bed (15), and said receptacle (15) is provided with a displacement lever (20) ) for a first movement component, one end of which is connected to a shaft (17) of the ejection sinker and the other end is pivotally connected to a control lever (28) for the first movement component, and a displacement lever (21) for a second movement component of one end is coupled to the ejector seat (15) and the other end is rotatably coupled to the control lever (29) for the second movement component, the displacement lever (20) for o the first movement component is disposed in the horizontal arm (Bi) of the second L-shaped cross-sectional formation and the shift lever (21) for the second movement component is in the vertical arm (B2) of the second cross-sectional formation; in the vertical arm (Ai) of the first L-shaped cross-sectional formation and the control lever (29) for the second movement component lies in the horizontal arm [A2] of the first cross-sectional formation, and the two control levers (28, 29) are mounted on a common shaft ( 23) in the central rotation region (P). 7. A strike according to claim 6, characterized in that the displacement lever (20) for the first movement component is connected to the shaft (17) of the bed (15) by means of a clutch (30) rotatably coupled to the displacement lever (20) and by means of a shaft (17), the shifting lever (20) for the second movement component is firmly connected directly to the bed [15] of the ejection sinkers. 8. A cotter strike according to any one of claims 1 to 7, characterized in that rollers constituting the control cam sensors (31a) are mounted on the actuating levers (24, 26, 29 and 25, 27, 28) of the movement components of the pendulum knitting elements. (32), supported by corresponding camshafts (33, 34), said camshafts being received by the region of the quadrangular formation defined by the arms (Αι, A2, Bi, Bz) of both L-shaped cross-sectional formations. 9. A padded strike according to claim 8, characterized in that the control levers (24, 26, 29; 25, 27, 28) are each formed by one arm (35a) of a knuckle lever member (80) whose second arm (35b). extends outwardly from the quadrangular formation to the cam (32) of the corresponding camshaft (33, 34) by contacting it with its sensor (31b) equidistant from the axis of rotation of the knuckle lever (80) as the first arm sensor (35a) (31a) forming a control lever (24, 26, 29; 25, 27, 28). A coton strike according to any one of Claims 1 to 9, characterized in that the quadrangular formations, each comprising one knitting head, are arranged parallel and symmetrically next to each other, wherein between the vertical legs (Ai) of the first L-shaped cross-sectional formation. a common camshaft (33) for actuating the control levers (24, 26, 29) located in both of these vertical arms (Ai) is located in the rectangles.