Engineering Guide
Bearing Identification System
| 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | |
| SERIES | Material | Type | Style | Basic Size | Special Feature | Closures | Ring Feature | ABEC Tolerance | Radial Play | Lubrication |
| METRIC |
M |
F |
- |
105 |
X |
ZZ |
EE |
A3 |
MC3 |
LO1 |
| INCH |
S |
F |
R |
156 |
X |
ZZ |
EE |
A3 |
MC3 |
LO1 |
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1 |
Material (M) (S) |
| Symbol M or Blank denotes SUJ2 (SAE52100) Chrome Steel. Symbol S denotes SUS440C (AIS1440C) Stainless Steel. |
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2 |
Type (F) |
| Symbol F is used to designate a Flanged bearing is required. | |
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3 |
Style (R) |
| Symbol R is used for all miniature and instrument bearings to signify Single Row Radial Retainer Type. | |
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4 |
Basic Size (105) (156) |
| Symbol R is used for all miniature and instrument bearings to signify Single Row Radial Retainer Type. | |
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5 |
Special Features (X) |
| Symbol X is used to designate a change in the standard bearing size. | |
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6 |
Closures (ZZ) |
| The following symbols designate available closures. No designation denotes and Open style bearing. Z-Single Shield, RS-Single Rubber Seal, VV-Double Non-Contact Seals ZZ-Double Shield, 2RS-Double Rubber Seals, ZZS-Removable Seals Z1-Shield on Flange Side, Z2-Shield Opposite Flange Side |
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7 |
Ring Feature (EE) |
| Symbol EE is used when the Extended Inner Rings are required. | |
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8 |
ABEC Tolerances (A3) |
| AFBMA Standards: A1-ABEC1, A3-ABEC3, A5-ABEC5, A7-ABEC7 ISO Standards: P0(A1) P6(A3) P5(A5) P4(A7) |
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9 |
Radial Play (MC3) |
| Symbol MC3 followed by numbers indicates the range of radial play. Example: MC3=0.005-0.013mm (0.0002 to 0.0005 inch) Example: MC4=0.013-0.020mm (0.0005 to 0.0008 inch) Symbol C designates larger size metric bearings. |
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10 |
Lubrication (LO1) - blank denotes manufacturer option |
| All bearings supplied with manufacturer's standard lubrication. LO followed by number indicates specific oil lube. LG followed by number indicates specific grease lube. LD denotes dry bearings. For specific lubrication, refer to the Lubrication Guide. |
Cage & Retainer Types
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W : ONE-PIECE STEEL CROWN TYPE |
J : TWO-PIECE STEEL RIBBON TYPE |
RJ : TWO-PIECE STEEL RIVET TYPE |
TW : ONE-PIECE NYLON CROWN TYPE |
V : FULL COMPLEMENT OF BALLS |
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The stainless steel pressed cage is inner ring guided. It shows excellent performance in low torque, low speed applications |
Consists of two mating steel pressings, the cover side and the finger side. Usually guided by the rolling elements and designed to reduce frictional torque. |
The RJ type cage is suitable for larger bearings with a high load carrying capacity. The two pieces are riveted together and are strong enough to withstand higher levels of vibration and acceleration. The cage is guided by the balls and reduces frictional torque. |
Molded nylon cage. Reduces the fluctuation in running torque. Suitable for high speeds. |
This type of bearing has no cage but maximum possible number of balls. Due to the fact that the inner and outer ring have a filling slot, the axial load carrying capacity of this bearing type is low. This type of bearing is suitable for high radial load, low speed applications. |
Design & Characteristics of Radial Ball Bearings
| BEARING STRUCTURE | |||||
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| BEARING DESIGN | |||||
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Standard |
(EE) Extended Inner Ring |
(V) Full Complement |
(N) With Snap Ring Groove |
(NR) With Snap Ring Groove and Snap Ring |
(F) With Flanged Outer Ring |
| BEARING CHARACTERISTICS | |
| Load: | Single row radial ball bearings with ball separated by a cage can support radial loads, axial loads and tilting movements. All full complement V-type ball bearing can support only radial loads and some low axial loads. |
| Speed: | Maximum permissible speeds for ball bearings are mainly related to the bearing design and size, cage type, bearing internal clearance, the method and type of lubrication, manufacturing accuracy, sealing methods and loads. |
| Torque & Noise Level: | Single row radial ball bearings are precision components and have low torque and noise levels. |
| Inclination of Inner/Outer Rings: | Shaft and housing seats with poor accuracy, fitting errors and shaft bending might cause inclination between the inner and outer rings, although the internal clearance of the bearing will permit this to a certain extent. Generally, the maximum permissible inclination between the inner and out rings is approximately 1 in 300. |
| Toughness: | Bearings under load deform elastically at the contact point between the rolling element and bearing ring. This is influenced by the bearing type, size, form and load. |
| Installation & Removal | The single row radial ball bearing is a non-separable bearing. Therefore, shafts and housings should be so designated to enable bearing inspection and replacement when necessary. |
| Axial Location: | Improved axial location is obtained with NR and F type bearings |
| BEARING DESIGN MATERIAL | |||||||||
| Standard material for rings and balls is a vacuum degassed high carbon chromium steel allowing for high efficiency, low torque, low noise level and long bearing life. For bearings requirng anti-corrosion or heat-resistance properties, marensitic stainless steel is used. | |||||||||
| CHEMICAL COMPOSITION OF BEARING MATERIAL | |||||||||
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Materials |
Symbol |
Chemical Composition % |
Equivalent |
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C |
Si |
Mn |
P |
S |
Cr |
Mo |
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| High Carbon Chromium Steel | SUJ2 | 0.95~1.10 | 0.15~0.35 | <=0.50 | <=0.025 | <=0.025 | 1.30~1.60 | <=0.08 | SAE52100 |
| Stainless Steel | SUS440C | 0.95~1.20 | <=1.00 | <=1.00 | <=0.040 | <=0.030 | 16.00~18.00 | <=0.75 | AISI440c |
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ZZ: Pressed Steel Shield |
ZZS Presseed Steel Shield |
TTS Teflon Seal w/ Snap Ring |
2RS Contact Rubber Seal |
Non Contact Rubber Seal |
| Non-contact shield pressed into outer ring. | Non-contact shield retained in outer ring. (Removable) | Non-contact shield retained in outer ring. (Removable) | Rubber seal fitted into outer ring. | Non-contact rubber seal fitted into outer ring |
Industry Engineering Lube
Common Oil Brands and Efficiency
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MANUFACTURER |
BRAND |
OUR CODE |
LUBRICATION BASE |
FLASH POINT ºC |
VISCOSITY |
OPERATING TEMP. ºC |
MIL STANDARD |
| SHELL OIL | AERO SHELL FLUID 12* | AF2 | DIESTER | 235 | 14(38ºC) | -50 TO +120 | MIL-L-6085A |
| SHELL OIL | AERO SHELL FLUID 3 | AF3 | PETROLEUM | 145 | 10.2(40ºC) | -55 TO +115 | MIL-L-7870A |
| ANDERSON OIL | WINDSOR LUBE L-245X | WL2 | DIESTER | 215 | 14(38ºC) | -55 TO +175 | MIL-L-6085A |
| TENNECO CHEMICALS | ANDERSOLL-401D | A4D | DIESTER | 220 | 12.7(38ºC) | -60 TO +125 | MIL-L-6085A |
| DOW CORNING | SH550R | D5R | METHYLPHENYL | 316 | 125(25ºC) | -40 TO +230 | - |
| NIHON OIL CO. | ANTIRUST P2100 | 002 | - | 166 | 13(40ºC) | - | VV-L-800 |
Common Grease Brands and Efficiency
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MANUFACTURER |
BRAND |
OUR CODE |
THICKENING AGENT |
LUBRICATION BASE |
DROP PT. ºC |
CONSISTENCY |
OPERATING TEMP. ºC |
MIL STANDARD |
| SHELL OIL CO. | ALVANIA NO.1 | AV2 | LITHIUM | MINERAL | 182 | 272 | -25 TO +120 | MIL-18709 |
| ALVANIA NO.3 | AV3 | LITHIUM | MINERAL | 183 | 233 | -20 TO +135 | - | |
| ALVANIA RA | AVS | LITHIUM | MINERAL | 183 | 252 | -40 TO +130 | - | |
| AERO SHELL GREASE NO. 7* | AG7 | MICROGEL | DIESTER | >260 | 288 | -73 TO +149 | MIL-G-23827B | |
| AERO SHELL GREASE NO.15A | AG5 | FLUOROTELOMER | SILICONE | >260 | 280 | -73 TO +260 | - | |
| ESSO | ANDOK B | AKB | SODIUM | MINERAL | 260 | 285 | -40 TO +120 | MIL-G-18709A |
| ANDOK C* | AKC | SODIUM | MINERAL | >260 | 205 | -20 TO +120 | - | |
| ANDOK 260 | AK2 | SODIUM | MINERAL | 200 | 260 | -30 TO +150 | MIL-G-3545B | |
| BEACON 325* | B32 | LITHIUM | DIESTER | 193 | 280 | -60 TO +120 | MIL-G-3278A | |
| KYODO YUSHI | MALTEMP PS NO.2* | PS2 | LITHIUM | DIESTER, MINERAL | 190 | 275 | -55 TO +130 | - |
| MALTEMP SRL* | NS7 | LITHIUM | ESTER | 191 | 245 | -40 TO +150 | - | |
| KLUBER LUB. | STABURAGS NBU12 | N12 | BARIUM | MINERAL | 220 | 270 | -34 TO +150 | - |
| BARRIERTA L55/2 | L55 | FLUOROTELOMER | FLUORINATED | - | 280 | -35 TO +220 | - | |
| BARRIERTA EL | IEL | FLUOROTELOMER | FLUORINATED | - | 280 | -50 TO +180 | - | |
| BARRIERTA IMI/V | IMI | FLUOROTELOMER | FLUORINATED | - | 280 | -50 TO +220 | - | |
| ISOFLEX NBU15 | NB5 | BARIUM | DIESTER, MINERAL | 200 | 280 | -40 TO +130 | - | |
| ISOFLEX TOPAS NB52 | NB2 | BARIUM | SYNTHETIC HYDROCARBON | 240 | 280 | -60 TO +170 | - | |
| ISOFLEX SUPER LDS18 | SL8 | LITHIUM | DIESTER | 190 | 280 | -60 TO +130 | MIL-G-7118A | |
| ISOFLEX LDS18 SPECIAL A | L8A | LITHIUM | DIESTER | 190 | 280 | -60 TO _130 | MIL-G-23827A | |
| DOW CORNING | MOLYCOTE 33M | M3M | LITHIUM | SILICONE | 210 | 260 | -70 TO +180 | - |
| MOLYCOTE 44M | M4M | LITHIUM | SILICONE | 204 | 260 | -40 TO +200 | - | |
| MOLYCOTE 55M | D5M | LITHIUM | SILICONE, ESTER | - | - | - | MIL-L-4343B | |
| MOLYCOTE BR2 PLUS | BR2 | LITHIUM | MINERAL | - | 280 | -30 TO +150 | - | |
| MOLYCOTE FS1292 | F19 | FLUOROTELOMER | FLUOROSILICONE | >232 | 310 | -40 TO +200 | - | |
| MOLYCOTE FS3451 | F35 | FLUOROTELOMER | FLUOROSILICONE | >260 | 285 | -40 TO +230 | - | |
| MOBIL OIL CO. | MOBIL GREASE NO. 28 | MG2 | BENTONITE | SYNTHETIC HYDROCARBON | >260 | 280 | -62 TO +204 | MIL-G-81322C |
| CALTEX | CHEVRON SRI-2 | SRL | UREA | MINERAL | - | - | -30 TO +175 | |
| DUPONT, E.I. | KRYTOX 240AC | K24 | FLUOROTELOMER | FLUORINATED | - | 282 | -35 TO +288 | MIL-G-27617A |
| NIHON OIL CO. | MULTINOCUREA | MNU | UREA | MINERAL | >260 | 290 | -20 TO +175 | - |
| SHINETSU SILICONE | SILICOLUBE G40M | G40 | LITHIUM | SILICONE | 210 | 260 | -30 TO +200 | - |
* Typical Standard Lubricants - as shipped from factory. Custom lubricants - are typically a factory order.
TEMPERATURE CONVERSION: °F - (1.8 X °C) + 32
ABEC Tolerances/ISO Ratings
Precision ball bearings are manufactured to standards established by the Annular Bearing Engineers Committee (ABEC) of the American Bearing Manufacturers Association (ABMA). These standards have been accepted by the American National Standards Institute (ANSI) and conform essentially to the standards set by the International Standards Organization (ISO).
IMPORTANT NOTE - The ABEC and ISO bearing standards are primarily concerned with bearing tolerances. While tolerance is an important factor in the performance of a bearing, there are many other factors that also affect the suitability of a bearing to its application. ABEC and ISO standards do not cover: radial play, raceway curvature, surface finish, material, ball complement, number, size or precision level, retainer type, lubrication, torque, cleanliness at assembly, packaging and other factors that may be essential to the desired bearing performance.
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ABEC/ISO TOLERANCE CHART |
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Inner Ring Tolerances - Inches (mm) |
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TYPE |
OD SIZE |
ABEC1 |
ABEC 3 |
ABEC 5 |
ABEC 7 |
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ISO Normal |
ISO P6 |
ISO P5 |
ISO P4 |
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Mean Bore Tolerance |
ALL |
0 to .709 |
0 to -.0003 |
0 to -.0002 |
0 to -.0002 |
0 to -.0002 |
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(0 to 18) |
(0 to -.008) |
(0 to -.005) |
(0 to -.005) |
(O to -.005) |
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2 PT Out of Roundness |
ALL |
0 to .709 |
NS |
NS |
0.0001 |
0.0001 |
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(0 to 18) |
(0.003) |
(0.003) |
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Bore Taper |
ALL |
0 to .709 |
NS |
NS |
0.0001 |
0.0001 |
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(0 to 18) |
(0.003) |
(0.003) |
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Radial Runout |
ALL |
0 to .709 |
0.0003 |
0.0002 |
0.00015 |
0.0001 |
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(0 to 18) |
(0.008) |
(0.005) |
(0.004) |
(0.003) |
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Face Runout With Bore |
ALL |
0 to .709 |
NS |
NS |
0.0003 |
0.0001 |
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(0 to 18) |
(0.008) |
(0.003) |
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Face Runout |
ALL |
0 to .709 |
NS |
NS |
0.0003 |
0.0001 |
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(0 to 18) |
(0.008) |
(0.003) |
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Width Variation |
ALL |
0 to .709 |
NS |
NS |
0.0002 |
0.0001 |
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(0 to 18) |
(0.005) |
(0.003) |
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Ring Width Toerance |
ALL |
0 to 1.1811 |
0 to -.005 |
0 to -.005 |
0 to -.001 |
0 to -.001 |
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(0 to 30) |
(0 to -.125) |
(0 to -.125) |
(0 to -.025) |
(0 to -.025) |
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ABEC/ISO TOLERANCE CHART |
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Inner Ring Tolerances - Inches (mm) |
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| TYPE | OD SIZE | ABEC 1 | ABEC 3 | ABEC 5 | ABEC 7 | |
| ISO Normal | ISO P6 | ISO P5 | ISO P4 | |||
| MEAN OD TOLERANCE | ALL | 0 to .709 | +0 to -.0003 | +0 to -.0003 | +0 to -.0002 | +0 to -.0002 |
| (0 to 18) | (+0 to -.008) | (+0 to -.008) | (+0 to -.005) | (+0 to -.005) | ||
| .709 to 1.1811 | +0 to -.0004 | +0 to -.0003 | +0 to -.0002 | +0 to -.0002 | ||
| (18 to 30) | (+0 to -.010) | (+0 to -.008) | (+0 to -.005) | (+0 to -.005) | ||
| MAX OD TOLERANCE LIMITS | OPEN | 0 to .709 | +.0001 to -.0004 | +.0001 to -.0004 | +0 to -.0002 | +0 to -.0002 |
| (0 to 18) | (+.003 to -.010) | (+.003 to -.010) | (+0 to -.005) | (+0 to -.005) | ||
| .709 to 1.1811 | +.0001 to -.0005 | +.0001 to -.0004 | +0 to -.0002 | +0 to -.0002 | ||
| (18 to 30) | (+.025 to -.010) | (+.025 to -.010) | (+0 to -.005) | (+0 to -.005) | ||
| 0 to .709 | +.0002 to -.0005 | +.0002 to -.0005 | +.00004 to .00024 | +.00004 to .00024 | ||
| SHIELDED |
(0 to 18) |
(+.005 to -.012) | (+.005 to -.012) | (+.001 to -.006) | (+.001 to -.006) | |
| .709 to 1.1811 | +.0002 to -.0006 | +.0002 to -.0005 | +.00004 to .00024 | +.00004 to .00024 | ||
| (18 to 30) | (+.005 to -.015) | (+.005 to -.012) | (+.001 to -.006) | (+.001 to -.006) | ||
| OD 2 PT OUT OF ROUNDNESS | OPEN | 0 to .709 | NS | NS | 0.0001 | 0.0001 |
| (0 to 18) | - | - | (0.0025) | (0.0025) | ||
| .709 to 1.1811 | - | - | 0.0001 | 0.0001 | ||
| (18 to 30) | NS | NS | (0.0025) | (0.0025) | ||
| SHIELDED | 0 to 1.1811 | - | - | - | - | |
| (0 to 30) | NS | NS | 0.0002 | 0.0002 | ||
| - | - | - | (0.005) | (0.005) | ||
| OD TAPER | OPEN | 0 to 1.1811 | NS | NS | 0.0001 | 0.0001 |
| (0 to 30) | - | - | (0.0025) | (0.0025) | ||
| 0 to 1.1811 | NS | NS | - | - | ||
| SHIELDED | (0 to 30) | - | - | 0.0002 | 0.0002 | |
| - | - | - | (0.005) | (0.005) | ||
| RADIAL RUNOUT | ALL | 0 to 1.1811 | 0.0006 | 0.0004 | 0.0002 | 0.00015 |
| (0 to 30) | (0.015) | (0.01) | (0.005) | (0.004) | ||
| OD RUNOUT WITH FACE | ALL | 0 to .709 | NS | NS | 0.0003 | 0.00015 |
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(0 to 18) |
NS | NS | (0.008) | (0.004) | ||
| FACE RUNOUT | STRAIGHT | 0 to 1.1811 | - | - | 0.0003 | 0.0002 |
| (0 to 30) | - | - | (0.008) | (0.005) | ||
| NS | NS | - | - | |||
| FLANGED | 0 to -1.1811 | - | - | 0.0003 | 0.0003 | |
| (0 to 30) | NS | NS | (0.008) | (0.008) | ||
| WIDTH VARIATION | ALL | 0 to 1.1811 | - | - | 0 to -.002 | 0 to -.0001 |
| (0 to 30) | NS | NS | (0 to -.005) | (0 to -.003) | ||
| FLANGE WIDTH TOLERANCE | 0 to 1.1811 | 0 to -.002 | 0 to -.002 | 0 to -.002 | 0 to -.002 | |
| (0 to 30) | (0 to -.050) | (0 to -.050) | (0 to -.050) | (0 to -.050) | ||
| FLANGE DIAMETER TOLERANCE | 0 to 1.1811 | +.005 to .002 | +.005 to .002 | 0 to -.001 | 0 to -.001 | |
| (0 to 30) | (+.125 to -.050) | (+.125 to -.050) | (0 to -.025) | (0 to -.025) | ||
Internal Clearance
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Bearing internal clearance in operation is an important factor that has a significant influence on other factors such as noise, vibration, heat and fatigue life. Radial ball bearings are usually classified by their internal radial clearance.
When measuring the internal clearance, the bearing is subjected to a standard load in order to ensure full contact between all bearing components. Under such a load, the measured value is larger than the actual value stated for radial clearance; this is due to elastic deformation. The differance is compensated by the factors given in the tables below. |
| RADIAL INTERNAL CLEARANCE OF SMALL AND MINIATURE BEARINGS |
Internal clearance is the play between outer ring, inner ring and rolling element. Generally, the amount of up and down movement of the outer ring with respect to the fixed inner ring is called the radial internal clearance and its right and left movement the axial internal clearance.| CLEARANCE MARK | MC1 | MC2 | MC3 | MC4 | MC5 | MC6 | |
| CLEARANCE | max | 0 | 3 | 5 | 8 | 13 | 20 |
| min | 5 | 8 | 10 | 13 | 20 | 28 | |
| NOTE: 1) STANDARD CLEARANCE IS MC3. 2) FOR MEASURING CLEARANCE, OFFSET BY COMPENSATION FACTOR LISTED BELOW. 3) Unit um | |||||||
| CLEARANCE MARK | MC1 | MC2 | MC3 | MC4 | MC5 | MC6 |
| COMPENSATION FACTOR | 1 | 1 | 1 | 1 | 2 | 2 |
| NOTE: MEASURING LOAD IS AS FOLLOWS: MINIATURE BEARINGS 2.5N (0.25kgf), SMALL BEARINGS 4.4N (0.45kgf), Unit um | ||||||
| RADIAL INTERNAL CLEARANCE OF STANDARD RADIAL BALL BEARINGS |
| NOMINAL BORE DIAMETER d(mm) |
CLEARANCE | ||||||||||
| C2 | C0 | C3 | C4 | C5 | |||||||
| OVER | INCL | MIN | MAX | MIN | MAX | MIN | MAX | MIN | MAX | MIN | MAX |
| 10 | 0 | 7 | 2 | 13 | 8 | 23 | 14 | 29 | 20 | 37 | |
| 10 | 18 | 0 | 9 | 3 | 18 | 11 | 25 | 18 | 33 | 25 | 45 |
| 18 | 24 | 0 | 10 | 5 | 20 | 13 | 28 | 20 | 36 | 28 | 48 |
| 24 | 30 | 1 | 11 | 5 | 20 | 13 | 28 | 23 | 41 | 30 | 53 |
| 30 | 40 | 1 | 11 | 6 | 20 | 15 | 33 | 28 | 46 | 40 | 64 |
| 40 | 50 | 1 | 11 | 6 | 23 | 18 | 36 | 30 | 51 | 45 | 73 |
| NOTE: 1. FOR MEASURING CLEARANCE, OFFSET BY COMPENSATION FACTOR LISTED BELOW. , Unit um | |||||||||||
| BORE DIAMETER OF NOMINAL BEARING d(mm) | MEASURING LOAD | COMPENSATION FACTOR | |||||
| OVER | INCL | N(kgf) | C2 | C0 | C3 | C4 | C5 |
| 10(INCLUDED) | 18 | 24.5 (2.6) | 3~4 | 4 | 4 | 4 | 4 |
| 18 | 50 | 49 (5) | 4~5 | 5 | 6 | 6 | 6 |
| NOTE: Unit um | |||||||
| RELATIONSHIP BETWEEN RADIAL INTERNAL AND AXIAL INTERNAL CLEARANCE |
| The axial internal clearance is established from the ball diameter, outer and inner ring raceway radius and the radial internal clearance. Usually it is about 10 times the value of the internal radial clearance. Selection of a small internal radial clearance or an extra large interference fit in order to reduce the internal axial clearance after mounting is not recommended. |
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| SELECTION OF BEARING CLEARANCE |
| Theoretically, maximum bearing life is with very slight preload. However, even a slight increase in this theoretical preload can have a considerably detrimental effect on the bearing life. Positive clearance should therefore be selected. MC3 is usually used for miniature or small bearings, standard clearance for general bearings and the clearance for thin section bearings should never be greater than "standard". |
| Operating Condition | Clearance |
| Clearance fit for inner and outer ring. Low axial load. No axial load carrying requirement. Select bearing with reduced radial clearance. Lower vibration and noise. Low speeds. | MC1,MC2,C2 |
| Lower frictional torque. Standard axial load. Average axial load carrying requirements. Slight interference fit for inner ring. Clearance fit for outer ring. Average/low speeds. | MC3,MC4,CN(C0) |
| Extremely low frictional torque. High axial load. High axial load carrying requirements. Heavy interfence fit to support high loads or shock loads. Large temperature gradient from inner ring to outer ring. High degree of shaft deflection. | MC5,MC6,C3,C4,C5 |
Maximum Permissable Bearing Speed
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Each bearing type has its own limiting speed. The theoretical speed that bearings can run at safely, even if heat generation by internal friction occurs, is called the maximum permissible speed. The permissible speed is related to bearing type, type of cage, lubricant type, load and cooling conditions to which the bearing is subjected. For contact rubber seals (2RS type), the permissible speeds are limited by the peripheral velocity of the seal lip. Normally, this is approximately 50 - 60% of that of non-contact rubber seals. If light contact rubber seals are required, this must be stipulated with the order. If high loads occur, the permissible speed values must be reduced and the following supplementary factors applied, except under standard operating conditions (Cr/P<12, Fa/Fr>0.2) |
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Compensation for maximum permissable speed dependent on load ratio. |
Compensation for maximum permissable speed under combined axial and radial load |
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| COMPENSATION FOR MAXIMUM PERMISSIBLE SPEED DEPENDENT ON LOAD RATIO | ||||||||
| Cr/P |
5 |
6 |
7 |
8 |
9 |
10 |
11 |
12 |
| COMPENSATION FACTOR |
0.72 |
0.79 |
0.85 |
0.90 |
0.93 |
0.96 |
0.98 |
1.00 |
| COMPENSATION FOR MAX PERMISSIBLE SPEED UNDER COMBINED AXIAL & RADIAL LOAD | ||||||||
| Fa/Fr | 0.25 | 0.50 | 0.75 | 1.00 | 1.25 | 1.50 | 1.75 | 2.00 |
| COMPENSATION FACTOR | 1.00 | 0.95 | 0.93 | 0.91 | 0.89 | 0.88 | 0.87 | 0.86 |
If the bearing operates at over 70% of the permissible speed value, a lubricant for high speed should be selected. The values for the permissible speed are for applications with horizontal shafts and with appropriate lubrication. With vertical shafts, only 80% of the maximum speed speed value should be used. This is necessary due to the reduced cage guidance and reduced lubricant retention in this type of application.
Bearing Usage
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NOTES ON SELECTING BEARINGS |
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NOTES ON HANDLING BEARINGS |
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BEARING USAGE |
| Problem | Cause | Remedy | |
| Noise | High pitched metalic noise |
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| Low pitched metallic noise |
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| Regular Noise |
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| Iregular noise |
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| Variable noise |
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| Heavy vibration |
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| Excessive heat generation |
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| Lubrication failure |
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Damage/Cause/Remedy
| Problem | Damage | Cause | Remedy |
| High pitched metallic noise |
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| Low pitched metallic noise |
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| Regular noise |
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| Irregular noise |
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| Variable noise |
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| Heavy Vibration |
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| Excessive Heat Generation |
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Ensure abutment face and fitting diameter are perpendicular |
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| Lubrication Failure |
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| Flaking |
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| Indentations |
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| Pick-up |
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| Electrical erosion |
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| Fracture |
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| Skidding |
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| Abrasion |
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| Corrosion |
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