SE459102B - BOOM SYSTEM IN WAVE MACHINE - Google Patents

Description

459 102 the coordinated movement between the barriers has gone out resp. in its tooth engagement with corresponding teeth in adjacent booms. xsnocöxrtst For the INVENTION rßxrnsxr The front The above storage principle for the fold-out boom has caused problems with the exact setting of the abutment forces of the fold-out boom against other booms. The storage principle means that the effective cogging grip between the fold-out boom and the other booms becomes dependent on the thickness of the tissue. In the case of thick grades, e.g. if up to cza 8 mm, the teeth will work on their tops. This means that large forces arise which strive to push out the fold-out boom during ongoing weaving. The wear becomes prominent in the teeth and the accuracy of the boom system's feed function suffers.

The present invention has for its object to propose a device which solves e.g. this problem. What can mainly be considered to be characteristic of the new device is i.a. that resp. end bearing for the boom in question comprises two storage parts which are different from each other, of which the first storage part is rotatably mounted in the frame of the weaving machine and the second storage part is made with a rotatable part and a rotatable part supporting the first boom. The first bearing part for at least one end bearing then carries teeth for the toothed grip with adjacent second boom / bars. The invention is also characterized in that a shaft pin extending inside the first bearing part and the first boom, or alternatively the second bearing part, provides rotational movement transmission between the first bearing part and the fabric boom by means of internally arranged arcuate couplings which allow the shaft pin to be inclined relative to the first longitudinal direction of the boom. In this way, the first boom is foldable out from the second boom while maintaining continuous engagement between the booms.

In one embodiment, the folding-out / fold-in movement of the first boom (fabric boom) is controlled by means of guide means arranged in the fabric of the machine 459 102. Said guide means are preferably rotatably mounted in the frame to enable tilting of the first boom around the storage points of the guide guides in order to vary the direction of deposition and thereby provide opportunities to control the abutment pressure against respective other booms / booms with the wire / tissue intermediate.

Said first bearing part is preferably mounted in two bearings located on opposite sides of the arcuate tooth coupling enclosed by the first bearing part and said teeth for the gear engagement with adjacent second boom / bars. The first storage part can be considered to have the shape of a gabled cylinder. Said axle pin is made at its ends with extended parts which support curved (spherical) bearing surfaces which co-operate only with the corresponding curved (convex) inner abutment surfaces in the first bearing part.

The second bearing part has a rotatable part which extends inside the torsionally fixed part with a bearing intermediate. The rotatable part protrudes outside the rotatable part with a flange, on which a part of the fabric surface of the fabric boom (rubber-coated) is mounted. Said torsionally fixed part in the second storage part is guided by said guide means which assign the torsionally resistant part its rotationally fixed position at the same time as they allow the displacement for the precipitation of the fabric boom.

At resp. end bearing for the fabric boom is the first bearing part with its associated bearings in the frame and said teeth for said tooth engagement 'F encapsulated together with the end bearings and teeth of the other boom (s) in a gearbox. The shaft pin is arranged to be able to tilt approximately 20 in relation to the longitudinal axis of the boom in question, which entails a total precipitation movement for the fabric boom relative to other booms of about 30 mm.

ADVANTAGES The above gives the great advantage that the cog grip between the booms becomes independent of the thickness of the tissue. The gears and the first bearing parts can be arranged in a gearbox enclosure together with the bearings and teeth of the other booms, which ensures a long service life. The bearings are built into the stand. In its 459,102 further developments, the invention also enables the individual setting of the contact pressure between different booms in the fabric boom system. The control function for the precipitation of resp. fold-out booms can be made simple and staff-friendly. The conversion of the weaving machine to weaving of different qualities and patterns can be performed easily and efficiently compared to before.

DESCRIPTION OF THE DRAWINGS A presently proposed embodiment of a device having the features significant to the invention will be described in the following with simultaneous reference to the accompanying drawings, in which Figure 1 shows in vertical section parts of a weaving machine with associated chest boom and a fabric boom system with three Figure 2 shows in longitudinal section an embodiment of the end bearing of the fold-out boom which comprises first and second bearing parts and a shaft pin which transmits rotational movements from the first bearing part to the boom, and Figure 3 in end view shows guide means, in which the movements of the fold-out boom are controlled.

BEST EMPLOYMENT Figure 1 shows the parts of a weaving machine affected by the invention which may per se consist of the weaving machine sold on the open market by Älmhults Bruk with the designation TM ~ l00 or TM ~ 200. The weaving machine comprises a breast boom 1 and a fabric boom system 2 consisting of two outer booms 3 and 4 and a middle boom 5. The woven fabric is indicated by Q and the web of the fabric runs from the breast boom down to the outside of the boom 3 and towards the boom 5 and over its mantle surface and further down towards the boom 4, from where the extending part ßa is fed further towards a collection unit not specifically shown. The booms 3, 4 and 5 abut against each other with a well-balanced contact pressure and the boom system provides the extraction movement of the fabric 6 woven in the weaving machine. To enable manual entry of the beginning of the fabric when starting a weave, the middle boom 5 can be folded out from the other two booms to a position shown dotted with 5 '. The movement of the homme is indicated by R. The booms are driven from a common drive source which is not shown specifically in the figure. The movements of the booms are coordinated to each other and this is achieved by the booms being in gear engagement with each other via teeth not shown in the figure. The booms are stored in end bearings in the loom of the weaving machine shown down 7.

Figure 2 shows an end bearing for the middle boom 5 in detail.

The second end storage is performed in an identical manner and should therefore not be described in more detail here. The bearings of other booms are made in a manner known per se.

Resp. end bearing comprises a first bearing part consisting of the parts 8a, 8b, 8c, 8d and 8e, a second bearing part consisting of the parts 9a, 9b, 9c, and a rotational movement transmitting shaft pin 10.

The first bearing part carries on its outer part 8b external tooth teeth 11 which are in engagement with corresponding tooth teeth on adjacent booms 12 and 13. The part 8a carries a shaft pin 8a ', by means of which the first bearing part is mounted in a cylindrical roller bearing 14 in the frame 7. The parts 8a and 8b are made of different materials and are assembled by means of holding means 15. The first bearing part is mounted to the frame 7 also by means of a second bearing 16 (conventional ball bearing). The part 8c serves as a bearing-supporting part in this case. The part 8d consists of a bushing-like part of durable material. The part 8b is cooperable with a bearing surface on the shaft 10 in accordance with the following. The parts 8c and 8d are held together with holding means 17 and the parts 8c and 8b with holding means 18. The part 8e consists of a sealing lid for the bearing 16. The lid is sealed against the part 8c by means of a sealing means 19. The first part has the shape of a cylinder provided with an end bearing the shaft pin 8a '. The cylinder space is shown with Sf. The second storage part comprises a rotatable part 9a and a part 9b rotatable relative thereto. Arranged between the parts is a spherical bearing 20. The part 9c serves as a lid for the bearing 20 to close inside the existing grease inside the bearing. The part 9b extends inside the torsionally fixed part 9a and has at its projecting part a flange 9b 'rear shoulder 9b "and one, at which flange and shoulder the fabric boom 5 is mounted.

A sheath surface coating Sa in gui or similar material on the fabric boom extends over the outside of the flange 9b '. The second storage part is thus cylindrical with an internal recess 9d.

The torsionally fixed part 9a is controlled by guide members Z1 described in more detail below, by means of which the boom and recess movements of the boom 5 are controllable.

The shaft pin 10 is provided at its ends with enlarged parts 10a resp. 10b. The part 10a is engaged via an arcuate coupling 22 with the first bearing part 8a-8e. The part 10a 'carries on its outside arcuate or spherical tooths 10a' which engage with straight teeth 8b 'the part 8b in the first bearing part. At its one end, the part 10a is provided with a spherical bearing surface 10a "which cooperates with a corresponding convex bearing surface 8d 'on the part 8d. The arcuate coupling and said bearing surfaces allow the shaft pin 10 to be inclined relative to a shaft 23 which can be considered to be the drive center for the boom 5 when it assumes its drive position according to Figure 1. The inclined position is indicated in Figure 2 by 10 'f ;. The angle of inclination is indicated by ÛÅ.The arc tooth coupling 22 and the recesses in the first bearing part, the the second bearing part and the fabric boom 5 can be made to allow different maximum skewings for the shaft pin.In the present case a maximum skew angle Ö¿ of about 20 total precipitation movement for the boom of about 30 mm is allowed, which gives an An area for the maximum The maximum deflection movement can be selected, for example, to between 20 and 40 mm. The shaft pin 10 is supported (abuts) against the part 8a by means of the spherical pin 24 which is axially locked. The part 10a is attached to the shaft 10, e.g. by heat shrinkage. The part 8c is sealed against the part 10a by means of a seal arranged to follow the movement of the shaft journal relative to the first bearing part. The length of the boom can be 5-30 meters.

The recess in the boom is shown with Sb. The second extended part 10b cooperates with the inside of the fabric boom 5 in a corresponding manner via a second arcuate coupling 26 which comprises arcuate or spherical teeth 10b 'on the extended part 10b and straight teeth Sc in the fabric boom. The shaft pin 10 extends a bit into the fabric boom and is spliced at its middle parts by means of splice members 10oc known per se.

Because the shaft journal is in engagement with both the first bearing part and with the fabric boom via the described arcuate couplings 22 resp. 26, the shaft pin will serve as a rotary movement transmitting means where the rotational movements from the first bearing part are transmitted to the fabric boom which can be driven in coordination with the first bearing part, which in turn receives drive from adjacent booms via the teeth 11. The fabric boom can rotate in its second bearing part 9a-9c relative to the first bearing part 8a-8e regardless of the degree of precipitation of the boom 5. In this way, the boom will always be in optimal driving engagement with the other booms. The gears on the booms can be built in together with the bearings 14 and 16 in an encapsulated gearbox which can be filled with oil. The arcuate couplings can operate in an oil environment thanks to the seals 25 and 25a.

Figure 3 shows guide means for resp. end storage. The guide member is formed with a first end part 27 provided with two parallel first side lugs 28, 29 with internal guide surfaces 28a and 28, respectively. 29a. Extending between and over the first side lugs is an element 30 fixed in the lugs, at its ends. The bearing housing 9a is provided with a first guide member 9e which guides against said guide surfaces 28a resp. 29a via its side edges and runs under the element 30. At the diametrically opposite side of the guide member 21 there are parallel other side lugs 31, 32. An element 33 extends over the lugs and is attached to them at its ends. The side lugs have internal guide surfaces 3la, 32a. The bearing housing 9a is provided with a second guide member 9f which guides against said guide surfaces 3la, 32a under the element 33.

At the end of the guide member 9f a bracket 34 is arranged for adjusting screws 35, 36, the ends of which are cooperable with the end surface of the guide member Z1. A lifting cylinder 37 acts with its piston 37a on the bearing housing 9a controlled in the guide member. The guide member is pivotally mounted at point 38 in a bearing shaft not specifically shown. Angle adjustments can be made by means of adjusting screws 39 and 40 arranged in frame parts 41, 42. The bearing housing and 459 102 homes are shown in a cooperating position for the boom with adjacent booms 3,4 (see figure 1). From this cooperating position, the bearing housing and the boom are displaceable by a distance A (eg 30 mm) by means of the cylinder piston 37a. The contact bearings (fine adjustment) with adjacent booms can be determined with the adjusting screws 35 and 36 respectively. 39, 40 which gives individual adjustability with resp. bom 3.4. In Figures 2, the achievable end positions of the moving parts are shown in dotted lines. The invention is not limited to the embodiment shown above as an example, but may be subject to modifications within the scope of the appended claims and the inventive concept.

Claims (10)

459 192 PATENT REQUIREMENTS Device at the first boom (fabric boom) included in a weaving machine which is mounted at its ends and at least at one end is in gear engagement with at least one adjacent second boom (5), characterized in that each end bearing comprises two in relation to different storage parts, of which the first storage part (8a-8e) is rotatably mounted in the loom (7) of the weaving machine and the second storage part is made with a rotatable part (9a) and a rotatable part (9b supporting the first boom (5) ), that the first bearing part on at least one end bearing carries teeth (11) for said tooth engagement, and that one inside the first bearing part (8a-8e) and the first boom (5), alternatively the second bearing part (9a-9b ), extending shaft pin (10) provides rotational movement transmission between the first bearing part (8a-Se) and the first boom by means of internally arranged arcuate tooth couplings (22, 26) in order to be inclined relative to the county of the first boom direction (23), the first boom (5) being foldable out from the second boom (3, 4) while maintaining continuous gear engagement between the first and second booms. Device according to claim 1, characterized in that the first boom at its end bearings is guided in guide means (21) to achieve a defined precipitation direction (R). '" Device according to claim 2, characterized in that the guide means are rotatably mounted in the frame (7) to enable tilting of the first boom around the storage points of the guide guides in order to vary the direction of precipitation (R) and thereby steer the abutment pressure individually against adjacent other booms / booms with the wire / tissue (6, 6a) intermediate. Device according to claim 1, 2 or 3, characterized in that the first bearing part is mounted in two bearings (14, 16) located on either side of the arcuate coupling (22) enclosed by the first bearing part and said teeth (ll) for the toothed grip with adjacent second boom. ß 459 102 10 Device according to one of the preceding claims, characterized in that the shaft pin (10) at its resp. ends are provided with an otherwise extended part in relation to the shaft journal (10a and 10b), respectively, which supports a curved abutment surface (10a ") cooperable with an internal corresponding curved abutment surface (8d ') in the first bearing part and that at shaft tilting movement The curved surface of the shaft pin moves relative to the abutment surface. Device according to one of the preceding claims, characterized in that the rotatable part (9b) extends inside the rotatable part (9a) in the second bearing part and out of the rotatable part with a bearing flange (9b ' ) for the first boom. 7. Device according to any one of claims 2-6, characterized in that the torsionally fixed part (9a) in the second bearing part is controlled by said guide means (Z1). Device according to one of the preceding claims, characterized in that in resp. end bearing the first bearing part (Sa-8e) with its associated bearings (14 and 16 respectively) in the frame and said teeth (ll) for said gear engagement are encapsulated together with the end bearings and teeth of the other booms (s) in a gearbox. Device according to any one of the preceding claims, characterized by - - f; characterized in that the shaft pin (10) and the recesses assigned to it in the first bearing part and the first boom / second bearing part and the arc tooth couplings (22, 26) are arranged to allow an inclination of the shaft pin (10) relative to the first boom. longitudinal axis of 1-30, preferably about eza 20. Device according to one of the preceding claims, characterized in that the shaft pin and the bearing parts (8a-8e and 9a-9c, respectively) and the first boom are arranged to allow a total precipitation movement of the first boom relative to the the second boom (s) of 20-40 m, preferably about 30 mm.