DE9421787U1 - Ball bearing with a raceway groove - Google Patents

Description

Ball bearing with a raceway groove

The present innovation relates to a ball bearing with a raceway groove for a straight-line or arcuate movement and in particular to the design of the raceway groove.

It is known that the ratio between the raceway groove radius and the ball diameter, referred to below as osculation s, can be kept constant over the entire area of the raceway groove or in some areas. The rigidity of such a ball bearing is heavily dependent on the osculation. According to HERTZ's theory, the contact pairing reaches high rigidities at s = 0.5. Osculation in this area means that the semi-axis grows faster with increasing load on the ball. If the ball is also loaded at a pressure angle, the contact point between the ball and the raceway groove moves towards the raceway groove edge (Fig. 1). If the load is sufficiently high, the raceway groove width is no longer sufficient to completely form the contact surface. The rigidity of the ball bearing is impaired from this load, the contact partners are subjected to great stress and the service life is reduced.

A ball bearing with a raceway groove for linear movement is known from DE 36 07 479. It is characterized in that each contact area of the raceway grooves arranged in the raceway guide part and in the sliding movement part with a ball is formed by at least two or more types of circular arcs and that the ball comes into contact with one of these circular arcs under a light load and with the majority of these circular arcs under a heavy load.

This type of raceway groove design creates pronounced peaks at the transition from one radius to the other, which cause an uneven load distribution.

The object of the invention is to eliminate the uneven load distribution without loss of rigidity, and thus to increase the service life while utilizing the entire load range of the ball bearing, and to reduce the rolling resistance.

According to the innovation, the problem is solved with the means mentioned in the protection claims and explained in more detail in the embodiments.

The curved line that forms the raceway groove is free of crests and has a radius of curvature at every point where the contact center is located, which forms a non-constant ratio with the ball radius in the area of the raceway groove width. By changing this ratio, the edge pressure between the rolling element and the raceway groove edge is shifted to the load area that is not used. The rigidity of the ball bearing is not affected.

The advantage of the solution is that the service life of the ball bearing is increased by making changes to the raceway groove geometry without any additional design effort, while utilizing the entire load range. In addition, the rolling resistance of the bearing is reduced.

The innovation is explained in more detail below using an example. The drawings show

Fig. 1 the arrangement of a ball in two raceway grooves under a light load,

Fig. 2 the arrangement of a ball in two raceway grooves under a heavy load,

Fig. 3 a sphere and illustration of a raceway groove with drawn coordinate system and radii,

Fig. 4 is a diagram showing the deflection as a function of the load,

Fig. 5 is a diagram showing the pressure angle as a function of the load.

Fig. 1 shows the arrangement of a ball 1 in two raceway grooves 2 under a light load. Under the force F _{1 ,} a contact area B ₁ or A ₁ with the length 2Xa ₁ is formed. This creates a pressure angle Oi ₁ . With a stronger load F ₂ , the contact area B ₂ or A ₂ increases and the pressure angle c< ₂ increases (Fig. 2).

Fig. 3 shows a ball 1 and the image of a raceway groove 2 with the coordinate system and radii drawn in. In the example shown, the raceway groove curvature radius at point A is approximately equal to the ball radius. The ratio of the raceway groove curvature radius r _L to the ball radius r _K increases in the direction of the raceway groove edge.

Fig. 4 shows a comparison between the stiffnesses of a bearing with constant osculation s and a bearing with variable osculation. Fig. 5 shows the corresponding

; &iacgr;&iacgr;

Pressure angle changes.

The vertex-free curve line that represents the raceway groove can be described by a polynomial according to equation 1. The range of validity of the polynomial is from 0 to x _limit . The coordinate system has its origin in the center of the sphere. The curve line begins at point A according to Fig. 3 and is symmetrical to the Y axis.

y = k ₀ + k _2i · x ²ⁱ + . . . + k _2n · x ²ⁿ (1)

i = 1,2,...,n

For the application, the accuracy of a 6th order polynomial is sufficient.

For a sphere diameter d _K = 2r _L = 6.35 mm, the following polynomial coefficients result:

k ₀ = 3.175

_k2 = -0.1562

k ₄ = -1.85385 ICr ³

k ₆ = -4.778 ICT ⁴ .

The nominal pressure angle is α = 45°.

Claims (3)

Protection claims 1. Ball bearing with a raceway groove for linear and
arc-shaped movements, consisting of a track support part and a movement part, with opposing, in both side areas of the track support part and the
moving part arranged raceway grooves and with a number of rotatable between the corresponding
balls inserted into opposite raceway grooves, characterized in that the curved line which forms the raceway groove (2) is free of apex and has a radius of curvature (r _L ) at each point where the contact centre is located, which has a variable radius in the area of the raceway groove width.
ratio with the radius of the sphere (r _K ). 2. Ball bearing with a raceway groove according to claim 1,
characterized in that the raceway groove curvature radius (r _L ) at point (A) is approximately equal to the ball radius (r _K ) and the ratio of raceway groove curvature radius (r _L ) to ball radius (r _K ) increases towards the raceway groove edge. 3. Ball bearing with a raceway groove according to claim 1,
characterized in that the raceway groove curvature radius (r _L ) has a maximum value at point (A) and the ratio of raceway groove curvature radius (r _L ) to ball radius (r _K ) decreases towards the raceway groove edge. 4 sheets of drawings