SE437551B - STORES FOR A AXEL ORGANIZED MARKETING TOOL - Google Patents

Description

7902958-3 Although non-encapsulating metal rollers protect the bearings from most contaminants, they still allow certain contaminants to enter through the openings between the holder and the shaft or collars mounted adjacent the bearings. These contaminants accumulate against the sealing surfaces or mix with the lubricant between the ring support of the outer bearing race and the outer surface of the outer bearing race ring. Consequently, the cooperating metal surfaces become scarred and wear very quickly or the bearing seal loses its flexibility and wears very quickly due to the total dirt that is packed next to it. As a result, premature bearing failure occurs.

To overcome these problems, a pendulum bearing is provided which guarantees free rotation of the shaft within the bearing block and which receives limited pivoting movement or throw of the shaft and its bearings relative to the bearing block. The bearing is not encapsulated in a rigid metal holder but uses a unique flexible sealing construction to prevent contaminants from penetrating between cooperating metal surfaces and to also prevent dirt from accumulating or packing next to the seal. More particularly, it is an object of the present invention to prevent contaminants from penetrating into the area between the ball bearings or antifriction elements, and also between the cooperating surfaces of the outer bearing race ring and its holder.

To prevent contaminants from penetrating the bearing, a uniquely designed seal is provided which has radially inwardly extending flange surfaces, which smoothly engage the outer peripheral surface of an inner bearing race ring, and an outwardly extending second, resilient sealing flange which grooves engage with the bearing block or the inner bearing receiving surface.

The second or outwardly extending resilient sealing flange may further be designed to abut the collar member adjacent the inner bearing race ring to prevent contaminants from penetrating between the collar and the bearing block.

A metal core may be provided inside the seal to better ensure that the second flange maintains its contact with the bearing block or the bearing receiving surface. A further object of the present invention is to provide an improved means for introducing lubricant into the bearing and between the cooperating metal surfaces.

The invention is described in more detail below in connection with the accompanying drawings, in which Fig. 1 is a partial view of a disc harrow and shows the bearing and its bearing blocks in combination with the frame shaft and blades of the discs, Fig. 2 is an enlarged and cut-away side view of Fig. 3 is a further enlarged partial view of the bearing shown in Fig. 2 and its seal, Fig. 4 is a view similar to Fig. 3 and shows a sealing structure utilizing a core; Fig. 5 is a view similar to Fig. 4 and shows another construction with a seal and a core, Fig. 6 shows a further alternative sealing construction with separate resilient sealing flanges, Fig. 7 shows another alternative sealing construction and core construction for mounting the seal to the outer bearing race ring and Fig. 8 shows a further modification of the sealing structure and the core structure for mounting it to the outer bearing race ring.

Fig. 1 shows a part of a typical disc harrow comprising a disc frame 10 and disc blades 12 supported on a shaft 14 which is supported by a bearing holder 16. The frame 10 also carries a scraper tube 18 attached thereto by means of U-bolts 20. , 22 and holder 24. Self-adjusting scrapers 26 are articulated with the aid of clamping arms 28 which are held on the scraper tube 18 and which are prestressed by means of tension springs 30 to contact with a surface of resp. plate leaves. The bearing bracket 16 comprises the structural arm 32 which is connected to the frame 10 by means of bolts 34 and which is connected to the punched flange halves 36 and 38 by means of bolts 40.

Fig. 2 shows in cross section the shaft 14, the bearing 46 and adjacent spacers 42 and 44, it being seen that the bearing 46 is supported within the punched flange halves 36 and 38. The shaft 14 carries an inner bearing ban ring 48 and an outer bearing ban ring 7902958-3 with a plurality of anti-friction elements or ball bearings 52 therebetween. The flanges 36 and 38 have an inner bearing receiving surface 56 formed as a section of a sphere and the outer surface 54 of the outer bearing race ring is formed complementary to the bearing receiving surface 56 for receiving therefrom.

Cast spacers 42 and 44 are located on each side of the bearing abutting the sides of the inner bearing race 48. The diameter of the portions of the spacers 42 and 44 adjacent the inner bearing ring 48 in the appropriate embodiment exceeds the diameter of the inner bearing. the outer surface of the bearing ring 48.

Fig. 3 shows in greater detail the unique design of the seal 58 supported by the outer bearing race 50. The resilient annular seal 58 includes first resilient flanges 60 extending radially inwardly and a second resilient flange 62 extending outwardly. Both the flanges 60 and the flange 62 are formed in one piece and are supported by the metal core 64 which is attached to an annular cup support 66 of metal which in turn is supported by the outer bearing band ring 50. The first flanges 60 of the seal extend radially inwards and abuts the outer peripheral surface 68 of the inner bearing race 48 as it rotates along the shaft 14 during field operations. The second resilient flange or wiper seal 62 has thicker cross-sections relative to the cross-sectional areas of the first flanges and abuts the inner surface 70 of the portion 72 of the wide flanges 36, 38 which extend axially outside and hang over the outer edge of the outer bearing ring. 50.

The embodiment shown in Fig. 3 as well as the alternative embodiments shown in Figs. 4 and 5 include a separate metal core or stiffening member 64 which, according to the embodiments in Figs. 3 and 4, has axially extending perforations 74 therethrough. The core 64 provides support for the wiper seal 62 to ensure its continued contact with the inner surface 70 of the portion 72 of the flanges during operation. The radially extending perforations 74 through the core 64 allow the first and second sealing flanges 60 and 62 to be formed in a F piece of the same material to thereby have increased elasticity and strength.

To return to Fig. 2, means for introducing Lubricant into the bearing are shown therein. A lubrication nipple 76 is supported by the flange half 36. Between the flange halves 36 and 38 a cavity 78 is formed which communicates with the lubrication nipple 76. A small opening 80 extends axially through the outer bearing band ring. A thin gasket 82 between the flange halves 36 and 38 seals this cavity or lubricant reservoir 78 against leakage when lubricant is introduced into the nipple 76.

Figs. 4 and 5 show substantially similar sealing structures with alternative core elements 64 and 84. The structure shown in Fig. 5 is designed for resilient contact between the wiper seal 62 and the outer coil 42 of the adjacent coil 42 to inhibit the penetration of dirt in the area 88 which is adjacent to the inwardly extending resilient flanges 60.

The core 64 shown in Fig. 4 is designed to provide additional support for the outer surface 90 of the wiper flange 62 to ensure better contact between it and the inner surface 70 of the flanges at the portion 72.

Figs. 6 and 7 show separate sealing flanges 92 and 94 which are connected to integral cup supports 66 and 66, respectively. 96 which make it possible to use different sealing materials in the manufacture of the sealing flanges 92 and 94.

According to Figs. 7 and 8, alternative shell support structures 96 and 98 are provided which include a corrugated surface applied to the wide outer bearing ring 50. According to Figs. 8, an alternative embodiment is provided in which a single core element of metal serves as stiffening means as well. as cup support 98 for applying the seal to the outer bearing ban ring 50.

Figs. 3, 4, 5 and 7 show shell supports 66 with vertically extending wall portions 100 which are inwardly spaced from and located adjacent to the innermost flange surface 102 of the inwardly extending wiper flanges 60. This wall portion 100 is arranged to when mounting the outer bearing ban ring 50 and the seal 58 on the inner bearing ban ring 48, ensure that the inwardly extending wiper flanges 60 are not turned and project with their ends towards the anti-friction means of the ball bearings.

Preferably, two or three bearing holders 16 are used to support the shaft 14 and its disc blade blades 12. Due to the vertical and horizontal forces to which the blades 12 are subjected during operation, and which forces are transmitted to the bearing holder shaft 16. , the shaft 14 must not be exactly co-oriented inside all bearing holders 16. The bearings 46 must therefore be self-adjusting and have the ability to compensate for the initial misalignment and for dynamic misalignment during operation.

As the disc harrow is pulled over the field and the disc blades 12 rotate, both vertical and horizontal forces are transmitted through the disc blades 12 to the shaft 14 and its supporting bearing structure. These forces are further transmitted to the plate frame by each of the bearing holders 16 whereby varying horizontal and vertical forces are transmitted to adjacent bearing holders 16. Consequently, the bearings bearing the shaft must be able to receive some throw relative to the shaft and pivoting movement of the holders 16 and the flanges 36 and 38 relative to the outer bearing ban ring 50. It is for this reason that the lubricant reservoir 78 must be arranged to lubricate the surfaces 56 and 54 between the flanges 36 and 38 and the outer bearing ban ring 50. In When the disc blades 12, the shaft 14 and the inner bearing banner ring 48 rotate during work in the field, water, dirt, sand and other contaminants will cover the holder 16 and the spacer coils 42 and 44. To return to Figs. 2 and 3, it can be seen that to prevent that these contaminants penetrate through the space between the inner surface 56 of the flange half 36 and the outer surface 54 of the outer bearing ban ring 50 and into the sm The tool reservoir 78 formed between the outer bearing ban ring 50 and the flange 36 strokes the seal 58 against the inner surface 70 of the flange 36. As the shaft 14, the inner bearing ban ring 48 and the spacers 42 and 44 rotate, the scraper flange 62 scrapers engage the outer circumference 86 of the coil 42. and seals against the entry of contaminants into the cavity 88. It is this sealing flange 62 which allows the use of flanges 36, 38 which together with the coils 42 and 44 form openings 104 of significant size which facilitate lateral pivoting of the flanges 36 , 38, around the outer bearing ban ring 50.

N Podda L .n 7902958-3 A V-groove depression 106 is provided in the periphery of the spacers 42 and 44 adjacent the bearing holder 16. This groove 106 allows wire and similar material to be wound around the same rather than sliding into the opening or gap 104 between the peripheries of the flanges and coils adjacent to the bearing rings.

At the same time as the present embodiments of the wiper seal all show flange surfaces in contact with the outer periphery of the coils 42 and 44 adjacent the inner bearing ban ring 48, such a contact is not always necessary. As long as the wiper flange 62 continues to abut against the inner surface 70 of the flange portion 72 and the inwardly extending sealing flange 60 continues to abut the outer peripheral surface 68 of the inner bearing ring 48, any dirt or contaminants that could penetrate between the flange portion 70 and the periphery of the players 42 and 44 to be slidably ejected through the gap 88 and 104 as the shaft 14, the coils 42 and 44 and the inner bearing ban ring 48 rotate in the bearing holder 16 thereby allowing the sealing flange 60 to provide post-relatively misaligned movement between the inner bearing ban ring and the outer bearing ban ring 50.

With this improved sealing construction, the expected service life of the seal, the bearing surface and therefore the bearing holder can be extended to minimize the lost time spent on replacement operations during the working season. * _. II _ h * - \ 'Hyä i _ i Uirå?

Claims (8)

7902958-3 PATENT CLAIMS 1. l. Bearings for axed tillage tools, in particular disc blades, the outer bearing ring of which is sealed against the inner bearing ring by means of a seal and the outer bearing ring being movable relative to the body receiving it, known as due to the fact that the seal (58) extends to the body (16) which receives the outer bearing ring (50) and is slidable thereon on relative movement. Bearing according to Claim 1, characterized in that the seal (58) has a flexible sealing flange (60) abutting the body (16) and a further sealing flange (62) abutting the inner bearing banner ring (48). Bearing according to claim 2, characterized in that the sealing flanges (60, 62) are formed in one piece. Bearing according to one or more of the preceding claims, characterized in that the seal (58) is provided with a stiffening core (64). 5. A bearing according to claim 4, characterized in that the stiffening core (64) is perforated. Bearing according to one or more of the preceding claims, characterized in that the sealing flanges (60, 62) consist of different materials. Bearing for a disc blade with spacers arranged on the side of the bearing according to one or more of the preceding claims, characterized in that the seal (58) extends to the spacer (42, 44). Bearing according to one or more of the preceding claims, characterized in that a radial lubricant bore (80) is arranged in the outer bearing ring (50). _..._- u