JP2014088891A - Rolling bearing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rolling bearing device which can suppress uneven distribution of a lubricant inside the bearing and prevent failure of the bearing part due to poor lubrication.SOLUTION: A rolling bearing device 1 comprises: an outer ring 2 in whose inner periphery an outer ring raceway 2a is formed; an inner ring member 3 in whose outer periphery an inner ring raceway 3a is formed; a plurality of rolling elements 4 which roll between the outer ring raceway 2a and the inner ring raceway 3a; a retainer 5 which retains the plurality of rolling elements 4; and a sealing device 6 which is fitted into an inner periphery 2d at an axial end of the outer ring 2 and slidably contacts the inner ring member 3 to seal an internal space 10 between the inner periphery of the outer ring 2 and the outer periphery of the inner ring member 3. A lubricant 30 is enclosed in the internal space 10. The rolling bearing device 1 comprises: a shield 7 which is fixed to the inner ring 3 and arranged on the rolling element 4 side relative to the sealing device 6; and an oil receiving portion 2d which extends to the rolling element 4 side in an outer periphery of the shield 7.

Description

  The present invention relates to a rolling bearing device using a sealing device, and more particularly to a rolling bearing device used in outer ring rotation.

  Conventionally, in a rolling bearing device, a contact type or non-contact type sealing device has been provided to prevent leakage of lubricant such as grease enclosed in the bearing and to prevent water and foreign matter from entering from the outside. Yes. For example, as a contact-type sealing device, a seal case is attached to both end openings of the outer ring, a seal member is attached to the inside of the seal case, and the seal lip is elastically brought into contact with a shaft component such as an inner ring or a shaft. Is known.

  By the way, this type of sealing device has a problem that a rolling bearing device used under rotation of the outer ring, particularly a bearing device provided with a tapered roller bearing, cannot sufficiently perform its intended function. That is, under the outer ring rotation, for example, the lubricant filled in the bearing easily flows to both ends of the bearing due to the centrifugal force accompanying the outer ring rotation, and the lubricant in the bearing is likely to be insufficient compared to the case of the inner ring rotation. In addition, since this type of sealing device is usually fixed to an outer ring that is rotationally driven, the point that centrifugal force is generated in the seal lip and the pressing force toward the inner diameter side is weakened also contributes to a decrease in sealing performance. Yes.

  As a measure to improve the above problems, a non-contact seal is further provided in the space sealed by the seal lip, and the seal clearance of the non-contact seal is set on the outer diameter side of the sliding contact portion between the seal lip and the shaft component. An outer ring rotation type rolling bearing device is proposed. (See Patent Document 1)

JP 2011-52775 A

  In the rolling bearing device disclosed in Patent Document 1, leakage of lubricant from the sliding contact portion between the seal lip and the shaft component can be reduced. However, the lubricant in contact with the rotating non-contact seal is scattered radially outward by centrifugal force and is not introduced to the axial rolling element side. Moreover, it is inevitable that a large amount of lubricant scattered radially outwards stays on the inner periphery of the fitting portion with the outer ring of the seal.

  There is a risk that a large amount of the retained lubricant leaks outside due to centrifugal force between the seal fitting portion of the outer ring and the outer periphery of the seal. For this reason, in the rolling bearing device of Patent Document 1, the effect of preventing uneven distribution of the lubricant inside the bearing is small, and the lubricating performance is not greatly improved.

  An object of the present invention is to provide a rolling bearing device that suppresses uneven distribution of a lubricant inside a bearing and prevents a failure of a bearing portion due to poor lubrication.

  In order to solve the above-described problem, the structural features of the invention according to claim 1 include an outer ring having an outer ring raceway formed on an inner periphery, an inner ring member having an outer ring raceway formed on an outer periphery, the outer ring track, A plurality of rolling elements that roll between inner ring raceways, a cage that holds the plurality of rolling elements, and an inner periphery of an axial end of the outer ring, and are in sliding contact with the inner ring member and the outer ring And a sealing device that seals an inner space between the inner periphery of the inner ring member and the outer periphery of the inner ring member, and a rolling bearing device in which a lubricant is sealed in the inner space, and is fixed to the inner ring, The sealing device has a shield disposed on the rolling element side, and has an oil receiving portion extending on the rolling element side on the outer periphery of the shield.

  According to the configuration of the present invention, the lubricant splashed radially outward by the rotation of the rolling elements and the cage is held in the oil receiving portion of the shield extending in the axial direction, and the seal as the sealing device Further, the amount of the lubricant staying on the inner periphery of the fitting portion with the outer ring can be reduced with respect to the configuration having no oil receiving portion. As a result, it is possible to reduce the amount of lubricating oil leaked to the outside through the gap between the fitting portion of the outer ring with the seal and the fitting portion of the seal with the outer ring. Further, the lubricant held in the oil receiving portion circulates along the oil receiving portion to the rolling element side, and is introduced into the bearing constituted by the outer ring raceway, the inner ring raceway, and a plurality of rolling elements. Is done.

  In order to solve the above-mentioned problem, the structural feature of the invention according to claim 2 is that the tip of the oil receiving portion on the rolling element side is on the rolling element side in a fitting portion of the seal with the outer ring. It is located in the said rolling element side from the edge part.

  According to the configuration of the present invention, the tip of the oil receiving portion on the rolling element side is positioned closer to the rolling element than the end on the rolling element side of the fitting portion with the outer ring of the seal, and the oil receiver The portion completely covers the inner circumference of the fitting portion with the outer ring of the seal, so that the amount of lubricant staying on the inner circumference of the fitting portion with the outer ring of the seal is further reduced and retained inside the bearing. Can do. Furthermore, it is possible to avoid the risk that the retained lubricant leaks outside through the space between the seal fitting portion of the outer ring and the outer periphery of the seal.

  In order to solve the above-mentioned problem, the structural feature of the invention according to claim 3 is that a minute gap for sealing is formed between the tip of the oil receiving portion on the rolling element side and the inner peripheral portion of the outer ring. It has been done.

  According to the above configuration, the amount of lubricant flowing out from between the front end portion of the oil receiving portion on the rolling element side and the inner peripheral portion of the outer ring is greatly reduced by the small sealing clearance. As a result, the amount of the lubricant staying in the inner periphery of the fitting portion with the outer ring of the seal is further reduced, and more lubricant can be retained inside the bearing.

  In order to solve the above-mentioned problem, the structural feature of the invention according to claim 4 is that the oil receiver has a lip at the tip of the rolling element side, and the lip is in sliding contact with the inner periphery of the outer ring. is there.

  According to the above configuration, the lip at the tip of the oil receiving portion on the rolling element side and the sliding contact between the inner periphery of the outer ring and the tip portion on the rolling element side of the oil receiving portion and the inner peripheral portion of the outer ring The lubricating oil can be prevented from flowing out from between the two. It is possible to further reduce the amount of the lubricant staying in the inner periphery of the fitting portion with the outer ring of the seal, and to keep the lubricant inside the bearing.

  In order to solve the above-described problem, the structural feature of the invention according to claim 5 is that the cage has an end on the sealing device side in the axial direction closer to the sealing device than an end surface on the bearing outer side of the rolling element. The end of the shield on the rolling element side of the shield is positioned radially outward and on the rolling element side from the radial outer side of the cage and the end on the sealing device side. .

  The lubricant adhering to the rolling elements and the cage moves to the shield side along the radial inner surface of the cage by the rotation of the rolling elements and the cage, and the cage from the end on the axial sealing device side. Spatters outward in the radial direction. According to the said structure, the scattered lubricant is reliably hold | maintained at the oil receiving part of the said shield extended from the edge part by the side of the axial direction sealing device of a holder | retainer to the axial direction rolling element side.

  As a result, the amount of lubricant remaining on the inner periphery of the outer ring insertion portion that is inserted into the outer ring in the outer periphery portion of the seal can be greatly reduced, and it passes between the seal fitting portion of the outer ring and the seal outer periphery. Thus, the amount of lubricating oil leaking to the outside can be further reduced. Further, more lubricant held in the oil receiving portion circulates along the oil receiving portion toward the rolling element and is introduced into the bearing.

  In order to solve the above-described problem, the structural feature of the invention according to claim 6 is that the shield has a disk part extending radially outward from a part fixed to the inner ring, and the disk part. The oil receiving part formed on the rolling element side from the inner side is formed in a shape in which the diameter of the axial direction rolling element side end part of the inner peripheral part is smaller than the diameter in the axial center of the inner peripheral part.

  According to the above configuration, the inner circumference of the oil receiving portion is concave outward in the radial direction, and more lubricant is more reliably held in the oil receiving portion.

  In order to solve the above-mentioned problem, the structural feature of the invention according to claim 7 is that the rolling bearing device is such that the inner ring member is stationary and the outer ring rotates.

  According to the above configuration, since the shield is fixed to the stationary inner ring, the shield does not rotate, and the lubricant held in the oil receiving portion does not scatter radially outward due to centrifugal force. The amount of the lubricant staying on the inner periphery of the fitting portion with the outer ring of the seal is further reduced.

  ADVANTAGE OF THE INVENTION According to this invention, the rolling bearing apparatus which suppresses the uneven distribution of the lubricant inside a bearing and can prevent the malfunction of the bearing part by poor lubrication can be provided.

It is sectional drawing of the rolling bearing apparatus of the 1st Embodiment of this invention. It is an enlarged view of the principal part of FIG. It is explanatory drawing explaining an effect | action of the rolling bearing apparatus of the 1st Embodiment of this invention. It is an expanded sectional view of the principal part of the rolling bearing apparatus of other embodiment of this invention.

  Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a sectional view of a rolling bearing device according to a first embodiment of the present invention.
FIG. 2 is an enlarged view of the main part of FIG. Since the rolling bearing device of the first embodiment is symmetrical in the axial direction, FIG. 2 shows only one main part.

  1 and 2, a rolling bearing device 1 includes an outer ring 2 in which two rows of outer ring raceways 2a are formed on the inner peripheral portion, and an inner ring 3 as two inner ring members in which inner ring raceways 3a are formed on the outer peripheral portion. A plurality of tapered rollers 4 as a plurality of rolling elements arranged in a freely rolling manner between the two rows of outer ring raceways 2 a and the inner ring raceways 3 a of the two inner rings 3, and a plurality of tapered rollers 4. Two retainers 5 to be held, two seals 6 as sealing devices, two shields 7, and grease 30 as a lubricant are provided.

  The outer ring 2 is an annular body made of a steel material such as bearing steel, and two rows of conical outer ring raceways 2a are formed in the axially central portion of the inner circumference with the outer diameter in the axial direction being a large diameter. Track end surfaces 2c are formed radially outward from the large-diameter side ends of the two rows of outer ring raceways 2a, respectively, and radially outer edges of both track end surfaces 2c are axially outward from the outer ring side surfaces 2b, respectively. Two rows of cylindrical seal fitting surfaces 2d extend.

  The two inner rings 3 are ring bodies made of a steel material such as bearing steel. The inner ring raceway 3a has a conical inner ring raceway 3a at the center in the outer peripheral axial direction, and the diameter of the inner ring raceway 3a is increased from the large-diameter end to the one end. A small flange 3f is formed from the small diameter side end of the flange 3c and the inner ring raceway 3a to the other end. In the large collar 3c, a large collar surface 3d that inclines in the direction of the inner ring raceway 3a from the end portion on the large diameter side of the inner ring raceway 3a extends to the outer circumference surface 3e of the large collar. The outer peripheral surface 3e of the large bowl is cylindrical, and the end opposite to the large bowl surface 3d is continuous with the large bowl side surface 3b extending radially inward.

  The cage 5 is made of a steel material such as a carbon steel plate, and is formed into an annular body by pressing. The large annular portion 5a is provided at one end portion in the axial direction, the small annular portion 5b is provided at the other end portion, and a plurality of column portions 5c that connect the large annular portion 5a and the small annular portion 5b in the axial direction. A plurality of pockets 5d for holding a plurality of tapered rollers 4 are partitioned and formed equally on the circumference by the large ring portion 5a, the small ring portion 5b, and the two column portions 5c.

  The tapered roller 4 is made of a steel material such as bearing steel and has a tapered rolling surface 4a, a large end surface 4b, and a small end surface 4c. Two rows of tapered rollers 4 are respectively held in a plurality of pockets 5d of two cages 5, the large end surface 4b is in contact with the large collar surface 3d of the inner ring 3, and the rolling surface 4a is connected to the outer ring raceway 2a and the inner ring. In contact with the raceway 3a, the bearing portion 20 is arranged together with the outer raceway 2a and the inner raceway 3a. Further, the large annular portion 5 a of the cage 5 protrudes outward from the large end surface 4 b of the tapered roller 4.

  The seal 6 includes a cored bar 6a formed in an annular shape by pressing a steel material such as a carbon steel plate, and a seal lip 6b made of an elastic body such as synthetic rubber. The cored bar 6a is composed of a disk part 6c and a cylindrical part 6d extending in the axial direction from the outer periphery of the disk part 6c, and a seal lip 6b is vulcanized on the inner peripheral part of the disk part 6c with the tip directed toward the axial cylindrical part. It is glued. The two seals 6 each have a cylindrical portion 6 d fitted and fixed to the seal fitting surface 2 d of the outer ring 2, the tip of the seal lip 6 b is in sliding contact with the large collar side surface 3 b of the inner ring 3, and the inner circumference of the outer ring 2 and the two seals 6. The inner space 10 between the inner ring 3 and the outer periphery of the inner ring 3 is sealed. The internal space 10 is filled with grease 30 as a lubricant.

  The shield 7 is made of a steel material such as a carbon steel plate, and is formed in an annular shape with a U-shaped cross-section by pressing. The shield 7 is formed with a cylindrical first cylindrical portion 7a as an oil receiving portion on one side of the outer periphery of the disc-shaped side plate portion 7b, and the inner periphery of the side plate portion 7b is in the same direction as the axial first cylindrical portion 7a. A second cylindrical portion 7c is formed. An end portion of the first cylindrical portion 7a opposite to the side plate portion 7b has an inclined portion 7f inclined inward in the radial direction at substantially the same inclination angle as the outer ring raceway 2.

  The outer diameter dimension of the first cylindrical portion 7a and the axial length from the side plate portion 7b of the first cylindrical portion 7a to the tip of the inclined portion 7f are inserted into the shield 7 at a predetermined position on the outer peripheral surface 3e. At this time, the dimension is such that a small sealing clearance Δ can be formed between the outer periphery of the inclined portion 7f and the outer ring raceway 2a.

  Each of the two shields 7 is fitted into a predetermined position on the outer peripheral surface 3e of the large inner surface 3e of the two inner rings 3 with the side plate portion 7b facing the large inner surface 3b side of the inner ring 3 and the second cylindrical portion 7c. It is fixed to the individual inner ring 3. At this time, the above-described minute gap Δ for sealing is formed between the outer periphery of the inclined portion 7f of the shield 7 and the outer ring raceway 2a. Further, the inner peripheral surface of the first cylindrical portion 7a including the inclined portion 7f of the shield 7 is located radially outward of the great annular portion 5c of the cage 5, and serves as an oil receiving surface 7e.

  Between the inner peripheral surface of the first cylindrical portion 7a of the shield 7 and the radially outer end of the large annular portion 5c of the cage 5, the side plate portion 7b of the shield 7 and the large annular portion of the cage 5 There are gaps between the end portions on the axial shield 7 side of 5 c and between the side plate portion 7 b of the shield 7 and the disk portion 6 c of the seal 6.

  Hereinafter, an example of an assembly process of the rolling bearing device 1 will be described. Two inner rings 3 in which two rows of tapered rollers 4 and two cages 5 holding the plurality of tapered rollers 4 are incorporated are incorporated into the outer ring 2 from both sides in the axial direction. In this state, the grease 30 is injected into the internal space 10 including the bearing portion 20 between the inner periphery of the outer ring 2 and the outer periphery of the two inner rings 3 from the open portions on both axial sides.

  Next, two shields 7 face the side plate portion 7b outward from the open portions on both axial sides. The second cylindrical portion 7c is fitted on the outer circumference 3e of the two inner rings 3 and is inserted into a predetermined position. Thereafter, the ends of the seal lips 6b of the two seals 6 are brought into sliding contact with the large flange side surface 3b of the inner ring 3, and the cylindrical portion 6d is fitted and fixed to the seal fitting surface 2d of the outer ring 2, thereby completing the assembly.

FIG. 3 is an explanatory view for explaining the operation of the rolling bearing device according to the first embodiment of the present invention.
In the rolling bearing device 1 according to the first embodiment, the grease 30 is pushed into the bearing portion 20 by the two shields 7 at the time of the completion of the assembly, and the lubrication condition of the bearing portion 20 is compared with the case where the shield 7 is not provided. Greatly improved.

Hereinafter, the operation of the rolling bearing device 1 of the first embodiment will be described with reference to FIG. In the following description, in the rolling bearing device 1, it is assumed that the inner ring 3 is stationary and the outer ring 2 is rotated. The white arrow schematically shows the flow of the grease 30.
The rotation of the outer ring 2 causes the plurality of rollers 4 to revolve together with rotation, and the cage 5 that holds the plurality of rollers 4 also rotates. The grease 30 enclosed in the bearing portion 20 is also rotated by the revolution of the plurality of rollers 4 and the rotation of the cage 5, and centrifugal force acts on the grease 30 due to its own weight.

  In the bearing portion 20, the grease 30 positioned radially inward of the cage 5 is pressed against the inner circumferential surfaces of the large annular portion 5 a and the column portion 5 c of the cage 5 by the centrifugal force, and the inner circumferential surface is inclined. And moves toward the end of the great ring portion 5a on the shield 7 side, and scatters radially outward from the end. The scattered grease 30 is received by the oil receiving surface 7e of the shield 7 and stays on the oil receiving surface 7e. Since the shield 7 is stationary, the grease 30 staying on the oil receiving surface 7e moves in the gravitational direction by its own weight and is returned to the bearing portion 20 via the outer peripheral surface 3e.

  Most of the grease 30 positioned radially outward of the cage 5 is pressed against the outer ring raceway 2a by the centrifugal force, and moves to the larger diameter side of the outer ring raceway 2a along the inclination of the outer ring raceway 2a. The grease 30 moved to the large diameter side reaches the inclined portion 7f of the shield 7, but a small sealing clearance Δ is formed between the outer ring raceway 2a and the outer periphery of the inclined portion 7f of the shield 7 and the outer ring raceway 2a. Thus, a large amount of grease 30 does not reach the cylindrical portion 6d of the seal 6 via the minute sealing gap Δ.

  Most of the grease 30 reaching the inclined portion 7f of the shield 7 stays on the oil receiving surface 7e via the inclined portion 7f of the shield 7. Further, a part of the grease 30 positioned radially outward of the cage 5 is directly received by the oil receiving surface 7e of the shield 7 by the centrifugal force and stays on the oil receiving surface 7e. The grease 30 staying on the oil receiving surface 7e moves in the direction of gravity by its own weight, and is returned to the bearing portion 20 via the outer peripheral surface 3e.

  In this way, the amount of grease 30 staying on the inner periphery of the cylindrical portion 6d of the seal 6 can be greatly reduced compared to the configuration without the oil receiving surface 7e of the shield 7, and the seal fitting portion 2d of the outer ring 2 can be reduced. And the amount of grease leaking to the outside via the space between the outer periphery of the cylindrical portion 6d of the seal 6 can be reduced. Further, the grease 30 held on the oil receiving surface 7 e circulates along the shield 7 and is introduced into the bearing interior 10.

  When the outer ring is fixed and the inner ring rotates, the effect that the grease 30 staying on the oil receiving surface 7e is returned to the bearing portion 20 through the outer peripheral surface 3e during rotation by the rotation of the shield 7 is not recognized. However, during the stop period, the grease 30 staying on the oil receiving surface 7e is returned to the bearing portion 20 through the outer peripheral surface 3e. Similarly to the case where the outer ring rotates, the grease 30 that has moved to the larger diameter side of the outer ring raceway 2a does not reach the cylindrical portion 6d of the seal 6 via the small sealing gap Δ.

  As described above, the rolling bearing device 1 according to the first embodiment can reduce the amount of the grease 30 staying on the inner periphery of the cylindrical portion 6d of the seal 6 and can reduce the amount of the grease 30 leaking to the outside. Further, the grease 30 held on the oil receiving surface 7e is introduced into the bearing, thereby suppressing the uneven distribution of the grease in the internal space 10 and preventing the rolling bearing device from malfunctioning due to poor lubrication.

  In the rolling bearing device 1 of the first embodiment described above, a minute gap Δ is formed between the tip of the first cylindrical portion 7a and the outer ring raceway 2a. In the present invention, as shown in FIG. The rolling bearing device 11 may be configured to have a lip 17g slidably contacting the outer ring raceway 2a at the tip of the first cylindrical portion 17a as an oil receiving portion.

  In the above-described embodiment, the first cylindrical portion 7a as the oil receiving portion has a cylindrical shape. However, in the present invention, the oil receiving portion may have another shape such as a spherical shape.

  In the above-described embodiment, the position of the end portion on the axial rolling element side of the first cylindrical portion 7a as the oil receiving portion of the shield 7 is inward in the radial direction of the outer ring raceway 2a. The position of the end of the portion 7a on the axial rolling element side may be a position as close to the rolling element as possible depending on the type of the bearing.

  In the above-described embodiment, the lubricant is grease. However, in the present invention, the lubricant may be a liquid lubricant other than grease such as high viscosity lubricating oil.

  In the above-described embodiment, the rolling elements are a plurality of tapered rollers in two rows. However, in this invention, the rolling elements may be rolling elements of other numbers or types such as a plurality of cylindrical rollers in a single row. .

1, 11 ... Rolling bearing device 2 ... Outer ring 2a ... Outer ring raceway 3 ... Inner ring (inner ring member)
3a ... Inner ring raceway 4 ... Tapered rollers (rolling elements)
5 ... Cage 6 ... Seal (sealing device)
7, 17 ... Shield 7a, 17a ... 1st cylindrical part (oil receiving part)
7b, 17b ... Disc part 7e, 17e ... Oil receiving surface 17g ... Lip 10 ... Internal space 20 ... Bearing part 30 ... Grease (lubricant)
Δ ・ ・ ・ Small gap for sealing

Claims (7)

An outer ring having an outer ring raceway formed on the inner periphery, an inner ring member having an inner ring raceway formed on the outer periphery, a plurality of rolling elements that roll between the outer ring raceway and the inner ring raceway, and the plurality of rolling elements are retained. And a sealing device that is fitted to the inner periphery of the axial end portion of the outer ring and seals the inner space between the inner periphery of the outer ring and the outer periphery of the inner ring member in sliding contact with the inner ring member. A rolling bearing device in which a lubricant is sealed in the internal space,
A rolling bearing having a shield fixed to the inner ring and disposed on the rolling element side with respect to the sealing device, and having an oil receiving portion extending on the rolling element side on an outer periphery of the shield. apparatus.   The tip of the oil receiving portion on the rolling element side is located closer to the rolling element than an end on the rolling element side in a fitting portion of the sealing device with the outer ring. The rolling bearing device according to 1.   The rolling bearing device according to claim 1, wherein a minute gap for sealing is formed between a tip end portion of the oil receiving portion and an inner peripheral portion of the outer ring.   The rolling bearing device according to claim 1, wherein a lip is provided at a tip of the oil receiving portion, and the lip is in sliding contact with an inner periphery of the outer ring.   In the cage, an end portion on the sealing device side in the axial direction protrudes from the end surface on the bearing outer side of the rolling element toward the sealing device side, and the end portion on the radially inner side of the shield and the rolling element side The rolling bearing device according to claim 1, wherein the rolling bearing device is located radially outward from the end of the cage on the sealing device side and on the rolling element side.   The shield has a disk part extending radially outward from a portion fixed to the inner ring, and the oil receiving part is formed in a cylindrical shape extending from the disk part to the rolling element side. The rolling bearing device according to any one of claims 1 to 5, wherein the rolling bearing device is provided.   The rolling bearing device according to any one of claims 1 to 6, wherein the inner ring member is stationary and the outer ring rotates in the rolling bearing device.

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