Engine, Gear Oil & Grease Viscosity / Grade Classifications Explained

We explain the mechanics behind the different grade classifications of car / motorcycle oils & greases.

Viscosity Classifications
INDUSTRIAL LUBRICANT CASSIFICATIONS

ISO (International Standards Organisation) viscosity classification. The ISO viscosity classification uses mm2/s (cSt) units and relates to viscosity at 40oC. It consists of a series of 18 viscosity brackets between 1.98 mm2/s and 1650 mm2/s, each of which is defined by a number. The numbers indicate to the nearest whole number, the mid points of their corresponding brackets. For example, ISO viscosity grade 32 relates to the viscosity bracket 28.8 to 35.2 mm2/s, the mid point of which is 32.0 mm2/s. This is illustrated in the table below, which shows the ISO viscosity grade numbers, the mid-points of each bracket, and the viscosity limits

This system is now used to classify all industrial lubricating oils where viscosity is an important criterion in the selection of the oil. Cutting oil and some other specialized products are more important in relation to grade selection.

Kinematic Viscosity at 40°C (mm 2⁄s)
ISO Viscosity Grade (ISO VG) Minimum Maximum Mid-Point
2 1.98 2.42 2.20
3 2.88 3.52 3.20
5 4.14 5.06 4.60
7 6.12 7.48 6.80
10 9.0 11.0 10.0
15 13.5 16.5 15.0
22 19.8 24.2 22.0
32 28.8 35.2 32.0
46 41.4 50.6 46.0
68 61.2 74.8 68
100 90.0 110 100
150 135 165 150
220 198 242 220
320 288 352 320
460 414 506 460
680 612 748 680
1000 900 1100 1000
1500 1350 1650 1500
GREASE CLASSIFICATIONS

NLGI Grease Consistency Classification

The commonly used grease consistency classification is that established in the USA many years ago by the National Lubricating Grease Institute (NLG). This classifies greases solely in terms of their hardness or softness; no other property or performance level is taken into consideration.

The classification consists of a series of consistency range, each of which is defined by a number (or numbers) 000 to 6. The consistency, defined by the distance in tenths of a millimetre, that a standard cone penetrates a sample of the grease number under standard conditions at 25oC. This system is used to classify industrial greases.

NLGI Grease Classification (National Lubricating Grease Institute
NLGI Consistency (Grade No.) ASTM Worked Penetration at 25°C
000 445 - 475
00 400 - 430
0 355 - 385
1 310 - 340
2 265 - 295
3 220 - 250
4 175 - 205
5 130 - 160
6 85 - 115
AGMA Specifications for Gear Lubricants

The American Gear Manufacturers Association (AGMA) have issued specifications and recommendations for gear lubricants used in various types of gear application. AGMA Standard 250.04 details specifications for rust and oxidation inhibited (R and O) and extreme-pressure (EP) lubricants used in enclosed gear drives. The viscosity brackets correspond to those given in ASTM D 2422 Standard Recommended Practice for Viscosity System for Industrial Fluid Lubricants.

AGMA Viscosity Grades for Enclosed Gearing
AGMA Lubricant No. Viscosity Limits of Former AGMA Classifications SUS at 100°F Corresponding ISO Viscosity Grade
1 193 - 235 46
2, 2 EP 284 - 347 68
3, 3 EP 417 - 510 100
4, 4 EP 626 - 765 150
5, 5 EP 918 - 1122 220
6, 6 EP 1335 - 1632 320
7 Comp, 7EP 1919 - 2346 460
8 Comp, 8EP 2837 - 3467 680
8 A Comp 4171 - 5098 1000

Oils marked ‘comp’ are compounded with 3 to 10% fatty material.
The AGMA Standard 251.02 details specifications for three types of open gear lubricants – rust and oxidation inhibited (R and O), extreme-pressure (EP) and residual type gear oils. In this case the viscosity brackets for the higher viscosity grades are measured at 100 C.
LUBRICANT VISCOSITY CLASSIFICATIONS / ENGINE OIL LUBRICANT CLASSIFICATIONS

SAE J300 September 1980 (Engine Oils)
The most widely used system for engine oil viscosity classification is that established by the Society of Automotive Engineers (SAE) in the USA. In this system two series of viscosity grades are defined – those containing the letter W and those without the letter W.
Grades with the letter W are intended for use at lower temperatures and are based on a maximum low temperature viscosity and a maximum borderline pumping temperature, as well as a minimum viscosity at 100C. The low temperature viscosity is measured by means of a multi-temperature version of ASTM D2602 ‘Method of Test for apparent Viscosity of Motor Oils at Low temperature using the Cold Cranking Simulator’. Viscosities measured by this method have been found to correlate with engine speeds developed during low temperature cranking. Borderline pumping temperature is measured according to ASTM D3829 ‘Standard Method for Predicting the Borderline PumpingBorderline Pumping Temperature of Engine Oil’. This provides a measure of an oils’ ability to flow to the engine oil pump inlet and provide adequate engine oil pressure during the initial stages of operation.

Oils without the letter W, intended for use at higher temperatures, are based on the viscosity at 100oC only. These are measured by ASTM D445 ‘Method of Test for Kinematic Viscosity of temperature and Opaque Liquids’. A ‘Multi-grade’ oil is one whose low temperature viscosity and borderline temperature satisfy the requirements of one of the W grades and whose viscosity at 100oC is within the stipulated range of one-W-grades.

Automotive Lubricant Viscosity Grades1
Engine Oils - SAE J 300, JUne 2001 (DEC. 1999)
SAE Viscosity Grade Viscosity (cP) at Temp (°C),Max
Cranking2 Viscosity (cP) at Temp (°C),Max
Pumping2 Viscosity4 (cSt) at 100°C
Min Viscosity4 (cSt) at 100°C
Max High-Shear Viscosity5 (cP) at 150°C and 10sec-1
0w 6200 at -35 60,000 at -40 3.8

5w 6600 at -30 60,00 at -35 3.8

10w 7000 at -25 60,000 at -30 4.1

15w 7000 at -20 60,000 at 25 5.6

20w 9500 at -15 60,000 at -20 5.6

25w 135000 at -10 60,000 at -15 9.3

20

5.6 <9.3 2.6
30

9.3 <12.3 2.9
40

12.5 <16.3 2.96
40

12.5 <16.3 3.77
50

16.3 <21.9 3.7
60

21.9 <26.1 3.7

1 - All values are critical specifications as defined by ASTM D3244

2 - ASTM D5293

3 - ASTM D4684. Note that the presence of any yeild stress detectable by this method constitutes a failure regardless of viscosity

4 - ASTM D445

5 - ASTM D4683, CEC L-36-A-90 (ASTM D 4741) or ASTM DS481

6 - 0w40, 5w40 & 10w40 grades

7 - 15w40, 20w40, 25w40 & 40 grades
AUTOMOTIVE GEAR LUBRICANT CLASSIFICATIONS

SAE J306 (Gear Oils): Again, the classification is based on the lubricant viscosity measured at low and/or high temperatures. The high temperatures values are determined according to method ASTM D445. The low temperature values are determined according to method ASTM D2983 ‘Method of Test for Apparent Viscosity at Low Temperature using the Brookfield Viscometer’ and are measured in mPa.s (c.P).

Multi-grade oil satisfies the viscosity requirements of one of the W grades at low temperatures and one of the non-W grades at high temperature.
It should be noticed that there is no relationship between the SAE engine oil and gear oil classifications. A gear lubricant and an engine oil having the same viscosity will have widely different SAE grade designation as defined in the two classifications.

Automotive Lubricant Viscosity Grades
Gaer Oils - Except SAE J 306, 1998
SAE Viscosity Grade ASTM D2983 Temperature °C for Viscosity of 150000mPa.S(1)
MAX ASTM D445(mm)2⁄s Viscosity at 100°C
MIN2 ASTM D445(mm)2⁄s Viscosity at 100°C
MAX
70w -553 4.1 -
75w -40 4.1 -
80w -26 7.0 -
85w -12 11.00 -
80
7.0 <11.0
85
11.0 <13.0
90
13.5 <24.0
140
24.0 <41.0
250
41.0 -

1 - Using ASTM D 2983, additional low temperature viscosity requirements may be appropriate for fluids intended for us in light-duty synchronised manual transmission.

2 - Limited must also be met after testing in CEC 1-45-T-93, Method C (20 hours).

3 - The precision of ASTM D 2983 has not been established for determinations made at temperatures below -40°C. This fact should be taken into consideration in any producer-consumer relationship.

Note: 1cP = 1 mPa.s; 1cSt = 1mm2⁄s
ISO Viscosity Grades

Viscosity System for Industrial Lubricants
ISO Grade Mid-Point Viscosity cSt. @ 40°C Viscosity, cSt @ 40°C
Min Viscosity, cSt @ 40°C
Max
2 2.2 1.98 2.42
3 3.2 2.88 3.52
5 4.6 4.14 5.06
7 6.8 6.12 7.48
10 10 9.00 11.0
15 15 13.5 16.5
22 22 19.8 24.2
32 32 28.8 35.2
46 46 41.4 50.6
68 68 61.2 74.8
100 100 90.0 110
150 150 135 165
220 220 198 242
320 320 288 352
460 460 414 506
680 680 612 748
1000 1000 900 1100
1500 1500 1350 1650
Approximate Comparison of Different Viscosity Scales

The following table is for the conversion of viscosities in one system to those in another system at the same temperature.
Kinematic Viscosity cSt Engler Degrees Redwood No.1 Seconds Saybolt Universal Seconds Kinematic Viscosity cSt Engler Degrees Redwood No.1 Seconds Saybolt Universal Seconds
1.0 1.0 28.5 - 20.0 2.9 86 97.5
1.5 1.06 30 - 20.5 2.95 88 99.6
2.0 1.12 31 32.6 21.0 3.0 90 101.7
2.5 1.17 32 34.5 21.5 3.05 92 103.9
1.22 33 36.0 22.0 3.1 93 106.0
3.5 1.16 34.5 37.6 22.5 3.15 95 108.2
4.0 1.30 35.5 39.1 23.0 3.2 97 110.3
4.5 1.35 37 40.7 23.5 3.3 99 112.4
5.0 1.40 38 42.3 24.0 3.35 101 114.6
*5.5 1.44 39.5 43.9 24.5 3.4 103 116.8
*6.0 1.48 41 45.5 25.0 3.45 105 118.9
*6.5 1.52 42 471 26.0 3.6 109 123.2
*7.0 1.56 43.5 48.7 27.0 3.7 113 127.7
*7.5 1.60 45 50.3 28.0 3.85 117 132.1
*8.0 1.65 46 52.0 29.0 3.95 121 132.1
*8.5 1.70 47.5 53.7 30.0 4.1 125 140.9
*9.0 1.75 49 55.4 31.0 4.2 129 145.3
*9.5 1.79 50.5 57.1 32.0 4.35 133 140.7
10.0 1.83 52 58.8 33.0 4.45 136 154.2
10.2 1.85 52.5 59.5 34.0 4.6 140 158.7
10.4 1.87 53 60.2 35.0 4.7 144 163.2
10.6 1.89 53.5 60.9 36.0 4.85 148 167.7
10.8 1.91 54.5 61.6 37.0 4.95 152 172.2
11.0 1.93 55 62.3 38.0 5.1 156 176.7
11.4 1.97 56 63.7 39.0 5.2 160 181.2
11.8 2.00 57.5 65.2 40.0 5.35 164 185.7
12.2 2.04 59 66.6 41.0 5.45 168 190.2
12.6 2.08 60 68.1 42.0 5.6 172 194.7
13.0 2.12 61 69.6 43.0 5.75 177 199.2
13.5 2.17 63 71.5 440 5.85 181 203.8
14.0 2.22 64.5 73.4 45.0 6.0 185 208.4
14.5 2.27 66 75.3 46.0 6.1 189 213.0
15.0 2.32 68 77.2 47.0 6.25 193 217.6
15.5 2.38 70 79.2 48.0 6.45 197 222.2
16.0 2.43 71.5 81.1 49.0 6.5 201 226.8
16.5 2.5 73 83.1 50.0 6.65 205 231.4
17.0 2.55 75 85.1 52.0 6.9 213 240.6
17.5 2.6 77 87.1 54.0 7.1 221 249.6
18.0 2.65 78.5 89.2 56.0 7.4 229 259.0
18.5 2.7 80 91.2 58.0 7.65 237 268.2
19.0 2.75 85 93.3 60.0 7.9 245 277.4
19.5 2.8 84 95.4 70.0 9.2 285 323.4

For higher viscosities, the following factors should be used.

Kinematic = 0.247 Redwood Saybolt = 35.11 Engler
Engler = 0.132 Kinematic Engler = 0.0326 Redwood
Redwood = 4.05 Kinematic Saybolt = 1.14 Redwood
Saybolt = 4.62 Kinematic Kinematic = 0.216 Saybolt
Kinematic = 7.58 Engler Engler = 0.0285 Saybolt
Redwood = 30.70 Engler Redwood = 0.887 Saybol

Note: The first part of the table mark with an * should only be used for the conversion of kinematic viscosities into Engler, Redwood or Saybolt viscosities, or for Engler, Redwood and Saybolt between themselves. They should not be used for conversion of Engler, Redwood or Saybolt into Kinematic viscosities
COMPARATIVE VISCOSITY CLASSIFICATIONS
a Diagram Comparative Viscosity Classifications

Note:

Viscosity can only be related horizontally.

Viscosities based on 95 VI single grade oils.

ISO and AGMA viscosities are specified at 40oC.

SAE 5W, 10W, 75W, 80W and 85W viscosities are specified at low temperature. Equivalent viscosities at 100oF and 210oF are shown.

SAE 90-250 (Gear Oils) and SAE 20-50 (Engine oils) are specified at 210oF/99oC.

Updated on: 07/01/2019

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