CURVED TRENCH BALL BEARING

Abstract

Disclosed is a curved trench ball bearing, which includes an outer ring 1, a set of steel balls 2, a set of retainers 3 and an inner ring 4. The raceways of outer ring 1 and inner ring 4 are used for inlaying steel balls. At least one of them is “S”-shaped curve arc raceway end to end, the other is linear or “S”-shaped curve arc raceway. The number of the “peak” and the number of the “valley” of the curve arc raceway are equal to or an integer times of the number of steel balls. By means of this structure, a bearing can achieve the displacement of reciprocating rectilinear motion while rotating, thereby simplifying a mechanical structure of a kneading roller.

Description

FIELD

The present disclosure relates to annular ball bearings and, in particular, to curved trench ball bearings belonging to the field of general machine parts.

BACKGROUND

General bearings are used to locate shaft parts, so that it can rotate flexibly. However, the general machine parts with the capable of axial displacement can not be produced. For the mechanisms with the capable of both rotation and axial displacements, such as the motion of rub squeeze rollers, the applications of general bearings will make the mechanism complicated.

In order to simplify mechanical structure of rub squeeze rollers and change rotary motion into reciprocating linear motion, the invention discloses a curved trench ball bearing.

SUMMARY

The technical scheme of the invention is that the linear arc groove of the inner and outer rings in traditional bearing is changed into a curve groove with a complete symmetry, and the number of the “peak” and “valley” of the curve is equal to or an integer multiple of the number of steel balls. In the process of the inner and outer rings rotation, the shaft is rotated and done the periodic reciprocating linear movement. The main contents are as follows;

The curved trench ball bearing includes an outer ring 1, a set of steel balls 2, a set of retainers 3 and an inner ring 4. The raceways of outer ring 1 and inner ring 4 are used for inlaying steel balls. At least one of them is “S”-shaped curve arc raceway end to end, the other is linear or “S”-shaped curve arc raceway. The number of the “peak” and the number of the “valley” of the curve arc raceway are equal to or an integer times of the number of steel balls 2.

A set of steel balls 2 is installed betty en the outer ring 1 and the inner ring 4 and fixed by a set of retainers 3. The step of “S”-shaped curve arc raceway in the outer ring 1 (the distance between two adjacent “peak” or “valley”) is equal to or integer times of spacing between the outer edges of steel ball 2 (the distance between two adjacent steel balls). Or the step of “S”-shaped curve arc raceway in the inner ring 4 is equal to or integer times of spacing between the outer edges of steel ball 2.

A set of steel balls 2 is installed between the outer ring 1 and the inner ring 4 and fixed by a set of retainers 3. The step of “S”-shaped curve arc raceway in outer ring 1 is equal to or integer times of spacing between the outer edges of steel ball 2. Or the step of “S”-shaped curve arc raceway in the inner ring 4 is equal to or integer times of spacing between the inner edges of steel ball 2.

There are three structures for the retainers 3. One is the rigid connection between the retainers 3 and the inner ring 4. One is rigid connection between retainers 3 and outer ring 1. Another is to keep free state neither the first nor the second structure.

The adjacent steps of “S”-shaped curve arc raceway are perfectly symmetrical curve or straight line.

The invented annular ball bearing has the following advantages

(1) The rotary motion can be changed into linear motion;(2) The mechanical structures of rubbing roller can be simplified;(3) It is simple structure and small volume.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG, 1 the unfolded drawing of outer ring of curve arc raceway.

FIG. 2 is the unfolded drawing g of inner ring of linear arc raceway.

FIG. 3 is structure drawing of curved trench ball bearings while inner ring moves to left (that is the steel balls are in the peak).

FIG. 4 is structure drawing of curved trench ball bearings while inn ring moves to right (that is the steel balls are in the valley).

The meanings of each mark in the figures are as follows:

1 is an outer ring, 2 are a set of steel balls, 3 are a set of retainers, 4 is an inner ring, R is radius of arc raceway, D is outside diameter of bearing, d is inside diameter of bearing, B is the width of bearing broadside, and b is the width of bearing narrowside.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Now the preferred embodiments combined with the above drawings are given.

EXAMPLE 1

The outer ring 1 is made into “S”-shaped curve arc raceway as shown in FIG. 1. The inner ring 4 is made into linear arc raceway as shown in FIG. 2. The retainers 3 and the inner ring 4 are fixed and rotated together, and the number of the “peak” and “valley” of the curve is equal to the number of steel balls.

Active oscillating curved trench ball bearings are produced as the above methods. The curved trench ball hearings whose inner ring 4 is linear raceway can also keep retainers 3 free. Such structures of the curved trench ball bearings are passive swinging either left or right as shown in FIG. 3 and FIG. 4. The active and passive swinging curved trench ball bearings are installed in pairs, which can reduce the accuracy of the installation position.

EXAMPLE 2

The inner ring 4 is made into curve arc raceway. The outer ring 1 is made into linear arc raceway. The retainers 3 and the outer ring 1 are fixed and rotated together, and the number of the “peak” and “valley” of the curve is equal to the number of steel balls. The curved trench ball bearings are produced as the above methods. In the process of the curved trench ball bearings rotation, the inner ring 4 is rotated and done the periodic reciprocating linear movement.

EXAMPLE 3

The arc raceways of both the outer ring 1 and the inner ring 4 are made into curve structures. The arc raceways of both the outer ring 1 and the inner ring 4 are made into curve structures and keep the retainers 3 free, which can increase the swinging range and reduce the accuracy of the installation position when installed in pairs.

Other preferred embodiments can be from the same principles and structural changes.

INDUSTRIAL APPLICABILITY

The invented curved trench ball bearings can be used for the mechanism rotating at the same time the shaft swings, such as swinging mechanism, rub squeeze mechanism, These mechanisms are, often used in agricultural equipment such as peeling, hulling etc.

Claims

1. The curved trench ball bearing includes an outer ring [1], a set of steel balls [2], a set of retainers [3] and an inner ring [4]. The raceways of outer ring 1 and inner ring 4 is used for inlaying steel balls. One of them at least is “S”-shaped curve arc raceway end to end, the other is linear or “S”-shaped curve arc raceway. The number of the “peak” and the number of the “valley” of the curve arc raceway are equal to or an integer times of the number of steel balls 2.

2. The curved trench ball bearing of claim 1, characteristics are as follows: wherein said a set of steel balls [2] is installed between the outer ring [1] and the inner ring [4] and fixed by a set of retainers [3]. The step of “S”-shaped curve arc raceway in outer ring [1] (the distance between two adjacent “peak” or “valley”) is equal to or integer times of spacing between the outer edges of steel ball 2 (the distance between two adjacent steel balls).

3. The curved trench ball bearing of claim 1, characteristics are as follows: wherein said a set of steel balls [2] is installed between the outer ring [1] and the inner ring [4] and fixed by a set of retainers [3]. The step of “S”-shaped curve arc raceway in inner ring [4] is equal to or integer times of spacing between the inner edges of steel ball [2].

4. The curved trench ball bearing of claim 1, there are three structures for retainers [3]. One is the rigid connection between retainers [3] and inner ring [4]. One is rigid connection between retainers [3] and outer ring [1]. Another is to keep free state neither the first nor the second structure.

5. The curved trench ball bearing of claim 1, the adjacent steps of “S”-shaped curve arc raceway are perfectly symmetrical curve or straight line.