The invention relates to a ball bearing assembly, particularly to a novel configuration of rolling balls with sustainable lubrication and motion mechanisms for improving performance under severe operating conditions.
Various types of sliding bearings possessing self-lubricating feature have been developed. However, the sliding bearings usually fail to long-term operate under severe conditions, such as shaft rotating at high speed, heavy load and strong vibration. Such failures are mainly caused by lack of structural strength and exhaust of lubricating media resulting in decreasing contact pressure and velocity (PV) limits, thus shaft could be directly contacted with axial hole to induce high frequency impacts, excessive wear and heat generation. In addition, poor initial running-in characteristics, deficiency of thrust load capacity and axial back-and-forth movement of the shaft are the industry urgent issues yet to be solved.
Ball bearings are generally formed by using the inner and outer races each with a raceway inside so that plural balls are interposed. According to applied load, the clearance between raceways is reduced in different degrees. Such effect will be occurred on each ball along the raceways rotation and revolution which will induce local excessive wear, grease away from the balls, loss of fitness, and ultimately cause failure. Other disadvantages include limited number of balls to be placed in, high cost, limited thrust load capacity, and weak structure. Thus long-term operation under the aforesaid severe conditions will face tough challenges.
The ball bearing assembly includes at least two units being axially coupled together between which at least one set of plural balls is installed to allow a shaft adapted to be run through and supported by the plural balls.
The invention can notably provide many advantages, such as:
The assembly provides sustainable lubrication mechanism to replenish and recycle the lubricating media in storage chamber and abutting seats.
The assembly provides plural balls with good rolling performance to prevent excessive wear during the initial running-in process.
The assembly provides a vast amount and diversified lubricating media to optimize lubricity, upgrade operating limit and prolong service life.
The assembly is well suited for small precision motors to support high rotating speed miniature shafts and enhance heat dissipation.
The assembly provides fewer modularized units and can be singly formed by precision moulds to simplify mass production and reduce costs.
The assembly provides at least two units axially coupled in an abutting manner to achieve loading length extensibility and radial load uniformity.
The assembly provides a superior motion mechanism of the ball to improve rolling freedom, reduce wear rate and uniform load allocation.
The assembly is more adaptable to pair with a novel three-section shaft to solve deficiency of the thrust load capacity and axial movement issues.
Each unit 10 is made from a dense or porous material and includes an outer periphery forming a mounting portion 13, two ends forming two connection portions 14, a circular central hole 12 axially running through the two connection portions 14, and plural hemispherical seats 15 being concaved on a connection portion 14 concentric to the central hole 12 to allow each ball 16 inside the seat 15 adapted to be partially protruded from the central hole 12. The curvature of the seat 15 is conformed to that of the ball 16. Plural abutting seats 25 are formed by abutting two sets of plural seats 15 defined in two adjacent connection portions 14 between the two adjacent units 10 to allow the plural balls 16 adapted to be disposed therein. So that the bearing set 1 containing the plural balls 16 between the two adjacent units 10 forms the ball bearing assembly adapted to be run a shaft 6 through protruding surfaces of the plural balls 16. As such, even the shaft 6 is in direct contact with the plural balls 16 during a initial running-in process, the wear rate is much lower than that of the sliding bearing in which the shaft 6 is direct wear with a wall surface of the axial hole.
In practice, the invention can be applied to different devices; in various embodiments depicted herein a motor is used as the example to facilitate discussion. As such, the ball bearing assembly utilizes the mounting portion 13 to be press-fitted into an inner periphery of a jutting chamber 7 located at each end of a motor housing 5 in the art. Thus the shaft 6 can be run through two stationary ball bearing assemblies in the motor and supported by two sets of plural balls 16. In particular, compared with the traditional bearing assemblies having an outer shell, the ball bearing assembly is more adaptable to a small precision motor to support a high rotating speed miniature shaft 6. The jutting chamber 7 in such a motor is limited to a small space, which is better able to house the assembly without the outer shell. Providing the ball bearing assembly with a simple structure and few modularized units 10 in a compact state can enhance the heat dissipation and form a larger storage chamber 35 for more lubricating media storage which will be discussed in the following embodiments.
The unit 10 further includes a convex ring 19 formed on the central hole 12 with a radial height lower than that of vertexes of the protruding surfaces. Two convex rings 19 are preferably formed on both ends of the assembly so as to minimize ingress of foreign matter and lubricating media out of the assembly. The convex ring 19 can be formed on the unit 10 integrally or separately. The lubricating media means lubricating oil and lubricant such as grease or hybrid lubrication agent containing solid lubricating grains that have a higher viscosity than the lubricating oil.
The units 10 are most likely to be made through the powder metallurgy technology to simplify mass production and form a porous structure with good permeability of fluid. Therefore the required density and dimensional accuracy of the units 10 can be singly formed by precision moulds through stamping processes. The lubricating media can be applied through vacuum impregnated with lubricating oil in the capillaries of the units 10 and further the lubricant can be filled in the plural seats 15.
When the shaft 6 rotates, the lubricating media is expanded due to receiving heat generated by tribology points 30 between the shaft 6 and the protruding surfaces and tribology interfaces between the plural balls 16 and the plural abutting seats 25. As a result, the viscosity of the lubricating media reduces and fluidity increases, along with capillary force generated by the capillaries and centrifugal force generated by the rotating shaft, the lubricating media can be infiltrated out to the plural abutting seats 25. Through the rolling of the plural balls 16 in the plural abutting seats 25, the lubricating media in a form of liquid film is brought to the protruding surfaces so as to continuously replenish through the tribology points 30. Meanwhile, the surplus lubricating media on the protruding surfaces is brought back to the plural abutting seats 25 so as to recycle the lubricating media. Further, because each ball 16 is pivoted by the abutting seat 25 with good rolling performance causes the tribology point 30 on the ball 16 being constantly changing, so that the load on the shaft 6 can be shared more evenly by the balls 16. Thus local excessive wear on the surfaces of the balls 16 for the traditional ball bearing can be avoided. The aforesaid superior motion mechanism of the plural balls 16 in the robust plural abutting seats 25 provides strong support for the shaft 6 and can replenish and recycle the lubricating media to greatly prolong the service life.
The unit 10a differs from the unit 10 mainly in that the unit 10a includes a groove 17 and plural notches 18 being formed respectively on the connection portion 14 in which the plural seats 15 are defined. The groove 17 is indented towards and through the mounting portion 13. The plural notches 18 are indented to communicate with the plural seats 15 and the groove 17. As such, plural partitions 21 and plural diaphragms 22 are formed on the connection portion 14. After placing the plural balls 16 into the plural seats 15, the corresponding two adjacent partitions 21 and two adjacent diaphragms 22 between the two adjacent units 10a are in contact with each other to form the bearing set 1a, and the corresponding two adjacent seats 15 and two adjacent notches 18 are respectively forming plural abutting seats 25 and plural passages 36.
The mounting portion 13 is formed in a shape and size mating the cavity 20 so that the bearing set 1a can be press-fitted into the casing 11 tightly. In addition, the mounting portion 13 sets at least one slot 26 formed axially thereon to latch on the corresponding at least one rib 24 of the cavity 20. Similarly, the slot 26 may also be formed on the cavity 20 to latch on the corresponding rib 24 formed on the mounting portion 13. Further optimizes precise positioning and structural robustness of the ball bearing assembly. As such, a storage chamber 35 is defined within the cavity 20 around two adjacent grooves 17 for storing more lubricating media and communicating with the plural abutting seats 25 via the plural passages 36. Providing the assembly with a sustainable lubrication mechanism can replenish and recycle the lubricating media within the plural abutting seats 25 for even distribution on the tribology points 30, which is further beneficial to reduce noise, improve load capacity and anti-vibration capability, and prolong the service life.
The lubrication mechanism is also adaptable to be formed by at least one groove 17 and at least one set of plural notches 18 being indented respectively on at least one of the two adjacent connection portions 14 in which the plural abutting seats 25 are defined. The at least one groove 17 is arranged away from the mounting portion 13 and the at least one set of plural notches 18 is arranged in fluid communication with the plural seats 15 and the at least one groove 17. So that the storage chamber 35 and the plural passages 36 can be formed respectively by the at least one groove 17 and the at least one set of plural notches 18, thereby similar to the first embodiment without the casing 11 also can facilitate the lubrication mechanism.
The loading length extensibility for the ball bearing assembly is further illustrated in accordance with different stack modes of the four units 10, 10a, and 10b. For example, a stack of the arrangement shown in
Accordingly, a desirable loading length of the ball bearing assembly can be realized by axially coupling of at least two units, regardless of whether the assembly has the casing 11 or not, and is adaptable to any unit disclosed in the invention to make possible combinations, including the groove 17 and the notches 18 with differences in shape, size, number and position and also the unit 10 not having the groove 17 and the notches 18.
Firstly, plural tendons 38 are set in the groove 17 to enhance structural strength of a unit 10d shown in
Secondly, the spherical region 15b defined in the unit 10d retains at least one spherical surface on the bottom of the seat 15 with surface area within 20% that of the seat 15 and sets remaining surface as the concave region 15a. As such, each ball 16 in the abutting seat 25 can be held and supported freely by two spherical pivots through a central axis 32 aligned with centers of the two spherical regions 15b. The so-called “held and supported” refers to that the position of the ball 16 surface relative to the two spherical regions 15b is changing at any time. Thus the motion of each ball 16 is pivoted through the central axis 32 which is also automatic centering a rotation axis of the ball 16. In the following, first uses a traditional shaft 6 to explain the motion mechanism of the ball 16. Due to the axis of the shaft 6 in parallel with the central axis 32, a tangential force of the shaft 6 applied to the tribology point 30 (see
Thirdly, as shown in
When the three-section shaft 9 rotates, by means of the two curved sections 9ab leaning against the two closest sets of plural balls 16, effectively eliminates the shaft 9 axial movement clearance and strongly supports the axial load applied to the shaft 9. In addition, the two curved sections 9ab apply tangential force on the two sets of tribology curves 31 causing the rolling angle of the ball 16 more susceptible to change. Thus the shaft 9 provides the ball 16 more rolling freedom and flexible tribology positions conversion to further optimize rollability of the ball 16.
Accordingly, the three-section shaft 9 is clearly applicable to pair with the ball bearing assembly formed by axially coupling of the at least two units 10, 10a, 10b, 10c, 10d between which at least one set of plural balls 16 is installed. Thereby the industry long-term urgent issues relating to poor initial running-in characteristics, deficiency of the thrust load capacity, and axial back-and-forth movement can be effectually solved at once.
Further, the unit 10, 10a, 10c, 10d with the seat 15 facing the cavity 20 can be integrally formed with an inner surface of the casing 11 at one end via the mounting portion 13 to reduce component number and simplify fabrication process for structural robustness and mass production.
While the preferred embodiments of the invention have been set forth for the purpose of disclosure, modifications of the disclosed embodiments of the invention as well as other embodiments thereof may occur to those skilled in the art. The invention is defined by the appended claims only.
Number | Date | Country | Kind |
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104137708 | Nov 2015 | TW | national |