CN105090251A

CN105090251A - Bearing for automobile

Info

Publication number: CN105090251A
Application number: CN201510446079.5A
Authority: CN
Inventors: 不公告发明人
Original assignee: Individual
Current assignee: Individual
Priority date: 2011-12-21
Filing date: 2011-12-21
Publication date: 2015-11-25
Also published as: CN102494018A; CN105041859A; CN105114450A; CN102494018B; CN105041860A; CN105065444A; CN105090237A; CN105041857A; CN105114451A

Abstract

The invention relates to a bearing for an automobile, the bearing comprises an inner ring, secondary inner rings tightly sleeving the inner ring, rolling columns distributed on the secondary inner rings, rollers arranged between adjacent pairs of rolling columns, annular bridge hoops sleeving respective rollers, secondary outer rings tightly sleeving the bridge hoops, and an outer ring tightly sleeving the secondary outer rings; the rolling columns are axially distributed, each rolling column is provided with an annular slot with an arc section, and the rollers are positioned between the annular slots of adjacent rolling columns; the inner rings of the bridge hoops are provided with arc slots suitable for movably matching with the rollers; a pair of the secondary inner ring are axially symmetrically distributed at the outer periphery of the inner ring, the edge of the outside of each secondary inner ring is provided with a folding edge extending outwards, and the outer end surfaces of the rolling columns are positioned at the insides of the folding edges; and a pair of the secondary outer rings are axially symmetrically distributed at the inner periphery of the outer ring, and the inner ring of the pair of secondary outer rings form a large annular slot for fixing the bridge hoops.

Description

Automobile bearing

Technical field

The present invention relates to a kind of bearing, specifically a kind of resistance less, be suitable in axis and radial load bearing.

Background technique

Bearing be a kind of for determining running shaft and other part relative movement positions, rise and support or the component of leading role, be the parts carrying gravity, transferring power.

The deficiency of existing bearing is: on the resistance produced when quite a few of power can be lost in bearing operation, this resistance mainly comes from the friction in bearing between roller and retainer, bearing is larger, and the resistance that its retainer produces is larger, and then the power of loss is larger.In addition, the axial load ability of existing bearing is less, limits its application.

Summary of the invention

The bearing that the technical problem to be solved in the present invention is to provide that a kind of structure is simple, resistance is less, be suitable in axis and radial load.

In order to solve the problems of the technologies described above, the invention provides a kind of bearing, comprising: secondary inner ring, the roller be distributed on secondary inner ring, be located at the roller between a pair adjacent roller, the annular bridge hoop be set on each roller, the outer ring that is tightly placed in the secondary outer ring on this bridge hoop and is tightly placed on this secondary outer ring; Described roller axial distribution, each roller is provided with the circular groove that cross section is circular arc, and described roller is between the circular groove of adjacent roller; The inner ring of described bridge hoop is provided with the curve bath being suitable for coordinating with described roller activity; Described secondary inner ring comprises axially symmetrical a pair, and the outer side edge of secondary inner ring has the flanging extended radially outwardly, and the exterior edge face of roller is in the inner side of this flanging; Described secondary outer ring comprises axis and is symmetrically distributed in a pair of described outer ring inner circumferential, and this inner ring to secondary outer ring forms one for fixing the large circular groove of described bridge hoop.

Particularly, the joint of the end face of the body of described secondary inner ring and the inner side surface of described flanging had oil groove, and this crosses oil groove entirety ringwise, for carrying more lubricant oil, to reduce resistance.

Further, there is between the inner side end of described a pair secondary inner ring the first gap, for carrying lubricant oil, to reduce resistance.

Further, there is the second gap for carrying lubricant oil between the inner side end of described a pair secondary outer ring, to reduce resistance.

During concrete enforcement, the internal diameter size of the quantity of described roller, the diameter of roller and bridge hoop is suitable for being fitted to each other, between the curve bath being engaged in bridge hoop inner ring to make the activity of described roller and the circular groove of adjacent roller, and the diameter of roller is made to be greater than the spacing of described a pair adjacent circular groove; Coordinating of circular groove on the curve bath of roller and bridge hoop inner ring, roller, limit the moving position of roller, and decrease movable resistance.

As a kind of scheme of global optimization, at same arcuate positions, described a pair secondary inner ring is respectively provided with a roller, this is to roller axle to symmetrical, and the inner end of contiguous each roller is located at by described circular groove; Described roller is between the circular groove of the adjacent roller of same circle distribution; The curve bath being suitable for coordinating with described roller activity of described bridge hoop inner ring comprises a pair that is oppositely arranged with described circular groove.

As the scheme optimized further, the end face of the body of described secondary inner ring is centroclinal inclined-plane, to improve axis, radial load ability further.

During concrete enforcement, described roller is truncated cone, and the tip portion of the roller of this truncated cone is described inner end; Described roller entirety is located on the body of single secondary inner ring.The roller of truncated cone is suitable for axial force to decompose radial direction, and therefore have better axial load ability, roller can not produce displacement; The roller clearance that the bearing of this structure adopts is less, is suitable for adopting a fairly large number of roller, is beneficial to and increases radial load ability.

Further, the tip portion of axially adjacent roller has gap, and to prevent from rubbing between the tip portion of adjacent roller, this gap is suitable for carrying lubricant oil, to increase lubricant oil space simultaneously.

As the scheme optimized further, the outer side edge of described secondary outer ring has the second flanging extended radially inwardly, and the exterior edge face of roller is in the inner side of this second flanging, to prevent roller axle to displacement, and improves radial load ability.

For improving the bulk strength of bearing, the inner side drive fit of described secondary inner ring has inner ring, and described secondary inner ring comprises a pair that is axially symmetrically distributed in described inner ring periphery.

The assembly method of above-mentioned bearing, comprises successively:

Described bridge hoop is located in described outer ring, then described a pair secondary outer ring is symmetricly set between outer ring and bridge hoop;

Described roller and roller are located at successively the inner ring of described bridge hoop;

Described a pair secondary inner ring is symmetricly set on inside each roller;

Described inner ring is a tight fit in the inner ring of a pair described secondary inner ring.

Technique scheme of the present invention has the following advantages compared to existing technology: (1) bearing of the present invention, eliminates the flower basket type retainer that traditional bearing adopts, avoids the power loss that retainer causes.Adopt the combination of bridge hoop, roller and roller to realize relatively rotating of Internal and external cycle, because bridge hoop, stress surface between roller and roller are arc-shaped surface, therefore resistance is less; Coordinating of circular groove on the curve bath of roller and bridge hoop inner ring, roller, limit the moving position of roller, described secondary inner ring and secondary outer ring play axial limiting effect respectively, and roller can not produce displacement; Therefore, bearing of the present invention has axial and radial load ability preferably.(2) roller adopted in twin columns bridge-type bearing of the present invention is truncated cone, and the tip portion of truncated cone roller is oppositely arranged, and the roller of truncated cone is suitable for axial force to decompose radial direction, and therefore have better axial load ability, roller can not produce displacement; The roller clearance that the bearing of this structure adopts is less, is suitable for adopting a fairly large number of roller, is beneficial to and increases radial load ability.(3) bearing of the present invention, is applicable to any types of bearings, such as automobile, wind-driven generator etc., relative to traditional bearing, can reduce resistance more than 50%; Large size bearing uses, Be very effective, be beneficial to energy-conservation.(4) bearing assemble method of the present invention, step is simple, it is easy to assemble, and product quality easily ensures.

Embodiment

Embodiment 1: single-column type bearing

See Fig. 1-2, the bearing of the present embodiment comprises: inner ring 1, the secondary inner ring 2 be tightly placed on this inner ring 1, the roller 3 be distributed on secondary inner ring 2, be located at roller 4, the annular bridge hoop 7 be set on each roller 4 between adjacent a pair roller 3, be tightly placed in the secondary outer ring 5 on this bridge hoop 7 and be tightly placed in the outer ring 6 on this secondary outer ring 5; Described roller 3 axial distribution, each roller 3 is provided with the circular groove 3-1 that cross section is circular arc, and described roller 4 is between the circular groove 3-1 of adjacent roller 3; The inner ring of described bridge hoop 7 is provided with the curve bath being suitable for coordinating with described roller 4 activity; Described secondary inner ring 2 comprises axis and is symmetrically distributed in a pair of described inner ring 1 periphery, and the outer side edge of secondary inner ring 2 has the flanging 2-1 extended radially outwardly, and the exterior edge face of roller 3 is in the inner side of this flanging 2-1; Described secondary outer ring 5 comprises axis and is symmetrically distributed in a pair of described outer ring 6 inner circumferential, and this inner ring to secondary outer ring 5 forms one for fixing the large circular groove 5-1 of described bridge hoop 7.

The joint of the end face of the body 2-2 of described secondary inner ring 2 and the inner side surface of described flanging 2-1 had oil groove 2-4, and this crosses oil groove 2-4 entirety ringwise, for carrying more lubricant oil, to reduce resistance.

There is the first gap 2-3, for carrying lubricant oil, to reduce resistance between the inner side end of described a pair secondary inner ring 2.

There is the second gap 5-2 for carrying lubricant oil between the inner side end of described a pair secondary outer ring 5, to reduce resistance.

The internal diameter size of the quantity of described roller 3, the diameter of roller 4 and bridge hoop 7 is suitable for being fitted to each other, between the curve bath being engaged in bridge hoop 7 inner ring to make the activity of described roller 4 and the circular groove 3-1 of adjacent roller 3, and the diameter of roller 4 is made to be greater than the spacing of described a pair adjacent circular groove 3-1; Coordinating of circular groove on the curve bath of roller and bridge hoop inner ring, roller, limit the moving position of roller, and decrease movable resistance.

As selectable optimized project, the outer side edge of described secondary outer ring 5 has the second flanging extended radially inwardly, and the exterior edge face of roller 3 is in the inner side of this second flanging, to prevent roller 3 axial displacement, and improves radial load ability.Described roller 4 generally adopts ball, also can adopt roller, to increase stability during bearing operation further.

Embodiment 2: twin columns bridge-type bearing

On the basis of above-described embodiment 1, the bearing of the present embodiment has following modification:

As Fig. 3, at same arcuate positions, described a pair secondary inner ring 2 is respectively provided with a roller 3, this is axially symmetrical to roller 3, and described circular groove 3-1 is located at the inner end of contiguous each roller 3; Described roller 4 is between the circular groove 3-1 of the adjacent roller 3 of same circle distribution; The curve bath being suitable for coordinating with described roller 4 activity of described bridge hoop 7 inner ring comprises a pair that is oppositely arranged with described circular groove 3-1.

Described roller 3 is in truncated cone, and the tip portion of the roller 3 of this truncated cone is described inner end; Described roller 3 entirety is located on the body 2-2 of single secondary inner ring 2.The roller of truncated cone is suitable for axial force to decompose radial direction, and therefore have better axial load ability, roller can not produce displacement; The roller clearance that the bearing of this structure adopts is less, is suitable for adopting a fairly large number of roller, is beneficial to and increases radial load ability.

The tip portion of axially adjacent roller 3 has gap, and to prevent from rubbing between the tip portion of adjacent roller 3, this gap is suitable for carrying lubricant oil, to increase lubricant oil space simultaneously.

Described roller 4 adopts ball.

As selectable optimized project, the end face of the body 2-2 of described secondary inner ring 2 is centroclinal inclined-plane, to improve axis, radial load ability further.

Described inner ring 1 can adopt plastic production, can remove when mounted.

Embodiment 3

The assembly method of the bearing described in above-described embodiment 1 or 2, comprises successively:

Described bridge hoop 7 is located in described outer ring 6, then described a pair secondary outer ring 5 is symmetricly set between outer ring 6 and bridge hoop 7;

Described roller 4 and roller 3 are located at successively the inner ring of described bridge hoop 7;

Described a pair secondary inner ring 2 is symmetricly set on inside each roller 3;

Described inner ring 1 is a tight fit in the inner ring of a pair described secondary inner ring 2.

Obviously, above-described embodiment is only for example of the present invention is clearly described, and is not the restriction to embodiments of the present invention.For those of ordinary skill in the field, can also make other changes in different forms on the basis of the above description.Here exhaustive without the need to also giving all mode of executions.And these belong to spirit institute's apparent change of extending out of the present invention or change and are still among protection scope of the present invention.

Accompanying drawing explanation

In order to make content of the present invention be more likely to be clearly understood, below basis specific embodiment and by reference to the accompanying drawings, the present invention is further detailed explanation, wherein

Fig. 1 is the cross-sectional configuration schematic diagram of the first bearing of the present invention;

Fig. 2 is the side structure schematic diagram of the bearing in Fig. 1;

Fig. 3 is the structural representation of the present invention's another kind of twin columns bridge-type bearing.

Claims

1. a bearing, is characterized in that comprising: secondary inner ring (2), the roller (3) be distributed on secondary inner ring (2), be located at the roller (4) between adjacent a pair roller (3), the annular bridge hoop (7) be set on each roller (4), the outer ring (6) that is tightly placed in the secondary outer ring (5) on this bridge hoop (7) and is tightly placed on this secondary outer ring (5);

Described roller (3) axial distribution, each roller (3) is provided with the circular groove (3-1) that cross section is circular arc, and described roller (4) is between the circular groove (3-1) of adjacent roller (3);

The inner ring of described bridge hoop (7) is provided with the curve bath being suitable for coordinating with described roller (4) activity;

Described secondary inner ring (2) comprises axially symmetrical a pair, and the outer side edge of secondary inner ring (2) has the flanging (2-1) extended radially outwardly, and the exterior edge face of roller (3) is in the inner side of this flanging (2-1);

Described secondary outer ring (5) comprises axis and is symmetrically distributed in a pair of described outer ring (6) inner circumferential, and this inner ring to secondary outer ring (5) forms one for fixing the large circular groove (5-1) of described bridge hoop (7);

At same arcuate positions, described a pair secondary inner ring (2) is respectively provided with a roller (3), this is axially symmetrical to roller (3), and the inner end of contiguous each roller (3) is located at by described circular groove (3-1);

Described roller (4) is between the circular groove (3-1) of the adjacent roller (3) of same circle distribution;

The curve bath being suitable for coordinating with described roller (4) activity of described bridge hoop (7) inner ring comprises a pair that is oppositely arranged with described circular groove (3-1).

2. the assembly method of bearing according to claim 1, is characterized in that comprising successively:

Described bridge hoop (7) is located in described outer ring (6), then described a pair secondary outer ring (5) is symmetricly set between outer ring (6) and bridge hoop (7);

Described roller (4) and roller (3) are located at successively the inner ring of described bridge hoop (7);

Described a pair secondary inner ring (2) is symmetricly set on each roller (3) inner side.