Evaluation of Two New Ortho-Alkylated Phenols as Lubricant Additives

Evaluation of Two New Ortho-AI kylated Phenols as Lubricant Additives J. D. BARTLESON Ethyl

Corp.

R e s e a r c h Laboratories, Detroit, Mich.

T h e discovery of the “orthoalkylation” reaction (8, 9, 11, 12) has made available commercially for the first time a s e r i e s of 2,6-derivatives of phenol and aniline. T h e s e products are excellent starting materials for s y n t h e s i s because of the reactivity of their para positions. 2,6-Ditert-butylphenol is of particular interest because its derivatives contain the hindered phenol structure (16) which is characteristic of the more effective phenolic antioxidants. This paper describes the evaluation of two derivatives of 2,6di-tert-butylphenol a s additives i n a number of lubricant applications. T h e compounds evaluated were 4,4 ’-methylenebis(2,6-di-tert-butylphenol), which will b e referred to as AN-2, and 2,6-di-tert-butyl-a-dimethylarninop c r e s o l , which will be called AN-3. AN-2

AN-3

C

C

C

c-c-c

c-c-c

c-c-c

I

I

lubricant applications involving elevated temperatures a n d a considerable degree of aeration, it would be desirable t o devise structures having minimum vapor pressures. This suggests the u s e of structures having higher molecular weights, provided t h i s c a n be accomplished without sacrificing desirable antioxidant properties. STRUCTURES OF AN-2 A N D A N 3

One of the commercially available antioxidants is 2,6di-tert-butyl-4-methylphenol, a compound which h a s been widely studied and the antioxidant properties of which are well established (I@. In c o m p r i s o n with t h i s compound, AN-2 might be visualized as a compound in which a 2,6di-tert-butylphenol group h a s replaced one of the hydrogens on the 4-methyl group. Similarly, the AN-3 structure represents the substitution of a dimethylamino group for one of the 4-methyl hydrogens.

I

Structures of A N - 2 and A N - 3

C H

O

D

c-c-c

C %%jOl

OH+C-N(

c-c-c

c-c-c

C

C

I

C

PRIOR STUDIES

Prior studies on phenolic antioxidants have described their relative inhibiting effects i n their preparation (14, petroleum products, and the mechanisms (5) by which they function, based on their oxidation products, Wasson and Smith (16) used a modified Staeger turbineoil test t o study t h e relationship between phenol substituents and antioxidant activity. Their work showed that a highly effective structure w a s one in which the 2- and 6-positions were occupied by tert-butyl groups and the 4-position by a methyl group. T h e use of smaller or less branched groups in t h e 2- or 6-positions resulted in much poorer antioxidants. Replacement of the methyl group i n the 4-position by ethyl or n-butyl groups produced improved antioxidants, while the presence of sec-butyl or terf-butyl groups in this position decreased antioxidant effectiveness. These observations suggest that the 4-position is the most logical one on which t o t e s t substituents in experiments designed to modify the 2,6-di-terf-butylphenol structure in order to obtain improved antioxidants. For

330

INDUSTRIAL AND ENGINEERING CHEMISTRY

I

c-c-c

c-Lc ,CHI

---N,

I

T e s t s have shown that AN-2 is a n excellent antioxidant for petroleum and d i e s t e r oils used in relatively hightemperature applications, such a s those encountered by crankcase oils and transmission fluids. In addition t o i t s antioxidant activity, AN-2 h a s been observed to minimize ring wear in gasoline engines under several conditions. Moreover, AN-2 is compatible with the most widely used motor-oil additives and frequently exhibits a marked beneficiai effect in the presence of these materials. The second compound, AN-3, is a n effective antioxidant in intermediate-temperature applications, such as are encountered by grease and steam turbine oil, where i t s good color stability is a desirable property. The polarity and alkalinity of the amine group in this compound may impart surface-active properties, such as dispersancy, and protection against rust and wear.

C

I

c-c-c

H

I

C

2,6di-teti-butyl4methylphenol

CHI

c-c-c

I I

C AN-2

AN-3

A N T I O X I D A N T E V A L U A T I O N STUDIES

In the evaluation studies, 2,6di-tert-butyl-4-methylphenol was included in order t o provide a comparison with a commercially available compound. A technical grade material w a s used. Technical grade AN-2 and AN-3 having a minimum purity of 98% were used. These materials are now available commercially. Steam-Turbinemoil T e s t s . The ASTM method D 943-54 (1) entitled “Oxidation Characteristics of Inhibited SteamTurbine Oils” w a s employed for the evaluation of steamturbine oils. This commonly used bench t e s t employs copper and iron wire catalysts, 60 ml. of water and 300 ml. of oil, a 95OC. temperature, and a n oxygen feed of 3 liters per hour. Periodic measurements of the acid number of the oil a r e indicative of oxidation, with acid numbers up t o a value of two being permissible. The results shown in Figure 1 were obtained using a solvent-refined Mid-Continent oil of 95 VI and 200 SUS a t 100°F. A t each additive concentration, AN-3 was superior to the other two additives. Moreover, use of AN-3 appeared to prevent a sharp break in the acid-number curve. T h i s w a s particularly evident in the t e s t a t 0.5% concentration, during which the acid number remained in the 0.1-2.0 range for several hundred hours. T h e basicity of AN-3 may be a factor in maintaining acid numbers a t this level. Similar results were obtained a t a lower additive concentration of 0.35% when a more highly refined oil (solvent extracted and sulfuric acid-treated) w a s used. With this oil (98 VI and 168 SUS a t 100°F.), AN-3 w a s again the best of the three additives, a s shown in Figure 2. During the turbine-oil tests, it w a s observed that a few VOL. 3, NO. 2

6.0-

1

i

I

I

I

I

I

1

I

I

I

0 5 % ADDITIVE CONCN

100

60

I

I

0 . 5 % ADDITIVE CONCN.

-

-

L

wl

4 w

4 0I 1

95r

I

3

?2

g

i

0 25% ADDITIVE CONCN

52

I 0 % ADDITIVE CONCN

6 0-

i

I

I

i

COMMERCIAL PHENOL

R ;,0AN I 0

Figure 1.

200

400

600 E00 TIME HOURS

100 -

95

COMMERCIAL

c

0

PHENOL

I

I

I

I

I

I

50

100

150

203

250

300

350

TIME HOURS

ASTM grease oxidation stability tests at 21OoF. on lithium-base grease

Figure 3.

-2

4

I 1000 I

I

I

I

I

I

I

ASTM steam turbine oil oxidation test on 95 V I solvent-refined oil

c r y s t a l s collected on the condenser i n the top of the oxidation cells. Following the example of Metro (13), t h e s e c r y s t a l s were isolated, purified, and identified. For both AN-2 and AN-3, the material w a s found t o b e 3,S-di-

tert-butyl-4-hydroxybenzaldehyde. T h i s same aldehyde was postulated a s the major degradation product of 2,6-di-tert-butyl-4-methylphenol by Wasson and Smith (16). However, under the turbine-oil test conditions described above, Metro found 2,6-di-tertbutyl-1,Cbenzoquinone to be the major degradation product. Grease Tests. T h e ASTM method D 942-50 (2) entitled “Oxidation Stability of Lubricating G r e a s e s by the Oxygen Bomb Method,” w a s used for the evaluation of greases. In this procedure, weighed samples of grease are placed i n g l a s s d i s h e s and subjected to 110 p.s.i. of oxygen i n a s t a i n l e s s steel bomb. Minimum l o s s of oxygen pressure is the criterion of effective inhibition. T e s t s were conducted at 210’F. and a t the 250’F. level used recently by Calhoun (3). T h e greases employed were a lithium-base

0

I

I

I

I

I

I

100

200

300

400

500

600

TIME HOURS Figure 4.

-.-.-*e.+AN-3 0

Figure 2.

1958

200

400

600 TIME HOURS

800

I IO00

ASTM steam turbine oil oxidation test on solvent-refined and acid-treated oil

ASTM grease oxidation stability tests at 25OoF. on lithium-base grease

grease and a calcium-base grease; neither grease contained a n antioxidant. T h e three phenolic additives were evaluated a t 0.25 and 0.50% concentration in the lithium-base grease a t 210°F., and a t 0.5% concentration in both greases a t 250’F. At CHEMICAL AND ENGINEERING DATA SERIES

331

IW -

90 -

-

80 -

m' D-

w'

5

70-

E

60-

m Y m LL a

? x

0

50 -

40-

30

Figure 7. Pond coking tart cornparisen of phenolic antioxidants on dioctyl sebosote, base o i l

20 -

i 0

I 25

I

I

50 75 TIME HOURS

I 100

Figure 5. ASTM grease o x i d d o n rtobiliiy t e s t s at 250°F. on colciurn-base grease with 0.5% additive concentrotion

210'F.. AN-3 showed a definite superiority aver the other two additives a t both concentrations, a s shown i n Figure 3. AN-2 was slightly t e t t e r than 2,6-di-ferf-hutyl-l-methylphenol i n both tests. T h e 250°F. test, which represented a much more severe t e s t condition, caused a wide spread in t h e oxygen-absorption r e s u l t s and in t h e appearance of t h e grease samples. On the basis of pressure drop, AN-3 w a s by far the most effective antioxidant in both types of grease, as shown in Figures 4 and 5. T h e superiority of AN-3 a l s o w a s evident in the appearance of the grease samples a t the conclusion of the test. For example, the lithium-base grease containing AN-3 w a s light-calmed and similar t o t h e original grease i n texture after 600 hours of 250°F.. while the other samples had darkened and undergone considerable change in texture. T h e s e results illustrate t h e good colorstability properties of AN-3 under oxidizing conditions. In regard t o t h e problem of grease discoloration when exposed t o sunlight, AN-3 is color s t a b l e on exposure t o ultraviolet radiation. Samples of lithium-base g r e a s e containing 0.5% of AN-3 were exposed to a General Electric 275-watt sunlamp for 30 hours at B d i s t a n c e of 12 inches. At t h e end of t h i s time, samples containing AN-3 showed

Figure 8.

Motor oil oxidation stobility t e s t cornpodson of phe-

nolic antioxidants (11 30O0F.

of the aromatic amine type underwent considerable darkening. Such a comparison is shown in Figure 6. T h e samples shown contained, respectively, no additive, 0.5% AN-3, and 0.5%phenyl-a-naphthylamine. Panel-Coking Tests. Panel-coking t e s t s were conducted in t h e P a n e l Coking apparatus (15) used to qualify synt h e t i c lubricants for j e t engines. T h e method involves t h e splashing of a lubricant onto a heated aluminum panel which is maintained at a controlled temperature. T h e weight of deposit formed on t h e panel is a measure of t h e oxidation stability of the luhricant. For t h e s e tests, t h e panel temperature w a s 600°F., the t i m e w a s 10 hours, a n d the s p l a s h e r w a s operated for 5 s e c o n d s e a c h minute. t h e phenolic additives w a s evaluated i n comFigure b. Effect of d t r o ~ i o l e tradiotion on odditiver in lithium-bore areose

L e f t . N o additive. Center. 0.5% AN-3. Right. 0.5% aromatic amine

VOL. 3, NO. 2

5

--

4

I

I ACID No X PENTANE INSOL

i 3.0 Y Lo

(D

G 2.5E

4

0 0

:2.03

a

: I ?

L

1.5-

e

0

I

40

0

I

I20

TEST HOURS

4

z Y

I 80

Figure 10.

1.0-

(D

Used oil IBSYIIS from hydramatic tranrmi..ion tests

4

Y (L 0

G

,

0.5-

0.0

0

0.5

1.0

AN-2

Figure 9.

1.5

CONCN.WT.

2.0

2.5

To

Effect of AN-2 on &dotion stability of ~ u t o m ~ t itronrmisrion c fluid

Test oil, commercial automatic transmission fluid

mercial dioctyl s e b a c a t e a t concentrations of 1, 2, and 3%. As shown i n Figure 7, use of AN-2 effectively minimized coke formation, giving extremely low r e s u l t s at the higher additive concentrations. AN-3 w a s moderately effective, while the 2,6-di-teit-butyl-4-methylphenol had l i t t l e value.

Bench-Scale Tests of Motor Oils. Bench-scale t e s t s of motor ails were performed using a modification of a Standard Oil (Ohio) method (IO) which involves aeration of the oil a n d iron catalysis. T h e t e s t conditions were: sample, 100 grams; temperature, 300OF.; time, 2 0 hours; air rate, 70 liters/hour; and catalyst, 0.05 wt% Fe,O, as soluble soap. T h e criteria of oxidation were t h e a c i d number and t h e per c e n t increase in viscosity of t h e used oil. A solvent-refined b a s e o i l of 95 VI and 200 SUS a t 100OF. w a s used, and each of t h e phenolic additives w a s t e s t e d i n t h e concentration range of 0 to 3%. In t h e s e tests, AN-2 w a s very effective, as shown in Figure 8. giving relatively complete inhibition a t Concentrations above 1%. Both AN-3 and 2,6di-tert-butyl-4-methylphenol were moderately effective a t concentrations of 2 and 3%, with A N 3 being superior. An indication of t h e antioxidant properties of AN-2

Figure 11. Chonncl bodies from hydromatic transmission tests on fluid 1

L e f t . Commercial automatic transmission fluid 1 Right. 1% AN-2

1958

CHEMICAL AND ENGINEERING DATA SERIES

333

I

5,

I

I

I

cn

1200

,

I. 600

:

400

0

E 8

2w 0

0.75

0.4

1.5

' 0

ADDITIVE. CONCN. WT % Figure 14.

I 0

40

I

0.4 0.75 1.5 ADDITIVE.CONCN. WT %

Chevrolet L-4 test evaluation of AN-2 ond A N 4

I

en

120

TEST HOURS Figure 12.

Used oil results from hydrametic transmission t e s t s on fluid 2

when used in combination with other additives is provided by a n experiment which employed a commercial T y p e A automatic transmission fluid as t h e t e s t oil. T h e oil, which had a VI (viscosity index) of 136 and a viscosity of 193 SUS (Saybolt Universal seconds) at 100°F., contained high concentrations of several m o t o r 4 1 additives, as indicated by the following analysis: 0.41% barium, 0.10% zinc, 0.10% phosphorus, and neutralization numbers of 2.04 (acid) and 2.79 (base). A s e r i e s of AN-2 concentrations w a s evaluated i n t h i s transmission fluid by using t h e procedure just described. As shown in F i g u r e 9. there w a s a linear relationship between concentration a n d inhibiting effect, as indicated by t h e change i n acid number of t h e used oils. A conesponding d e c r e a s e in sludge and varnish formation accompanied the change in acidity. AN-2 concentrations of

Figure 13.

0

0.4 0.75 1.5 ADDITIVE CONCN WT%

Figure 15.

-

0

0

0.4 0.75 1.5 ADDITIVE CONCN WT 'b

Effect of AN-2 and AN-3 on r i n g weor in Chevrolet L-4 t e s t

1% or higher showed a large antioxidant effect. T h e s e r e s u l t s illustrate t h e compatibility of AN-2 with an oil containing a variety of commercial additives, and they show that AN-2 is a n effective antioxidant i n t h e presence of t h e s e additives. Hydramatic Transmission Tests. T o extend t h e s e ob-

Reor clutch plates from hydramatic ironsmission tesl

on fluid 2 L e f t . Commercial automatic transmission fluid 2 Right. 0.5% AN-2

334

INDUSTRIAL AND ENGINEERING CHEMISTRY

VOL. 3, NO. 2

Figure 16.

Top rings from Chevrolet L-4 t e s t s

Upper. Base oil Lower. Base oil

servations, t e s t s were conducted in a 1957 Oldsmobile Jetaway Hydramatic transmission. T h e t e s t time w a s 140 hours, a n d a n oil temperature of 275OF. w a s maintained. T h e input speed w a s 1800 r.p.m., and an %second s h i f t cycle from third gear to fourth t o third w a s used. T h e fluids tested were t h e commercial fluid described above (fluid til) and this same fluid with 1%of AN-2 added. In t h e s e t e s t s , AN-2 showed a strong antioxidant effect. A s indicated by t h e used-oil properties shown i n Figure 10, the AN-2 extended t h e induction period by 50 hours, and a t the conclusion of t h e t e s t gave an acid-number increase and pentane-insalubles content which were less than half of those obtained with t h e commercial fluid. There w a s also a marked difference i n t h e visual appearance of the transmissions from t h e s e fests. T h e parts from t h e t e s t on commercial fluid were heavily sludged and varnished, while those from t h e t e s t using the fluid containing AN-2 were clean. Typical of t h e parts from t h e s e t e s t s me t h e channel bodies shown in Figure 11. A similar study w a s made using another T y p e A commercial transmission fluid (fluid 2). T h i s fluid contained a widely used additive package formulation a n d was different in chemical composition from fluid 1 as indicated by i t s analysis: 0.75% ash, 0.39% barium, 0 z i n c content, 0.023% phosphorus, a n d 0.45 acid number. Transmission t e s t s using t h e above conditions were conducted on t h e commercial fluid and the fluid Containing 0.5 and 1.0% of added AN-2. T h e b a s e fluid underwent considerable oxidation and, as illustrated in F i g u r e 12, showed a large change i n a c i d number a f t e r only 40 t e s t hours. Both AN-2 concentrations gave excellent inhibition with t h e higher concentration showing virtually no change i n used oil properties. Both AN-2 concentrations a l s o gave completely c l e a n transmissions, i n contrast t o the severe sludging which w a s observed for t h e commercial fluid. T h e rear clutch plates shown in Figure 13 a r e representative of t h e parts from t h e s e tests, with and without AN-2. Chevrolet L-4 Tests. T h e Chevrolet L-4 t e s t (6) is a widely used procedure for evaluating the oxidation stability and bearing-carrasian properties of motor oils. A bulk-oil temperature of 280°F. is maintained during the 36-hour test, and two copper-lead bearings a r e weighed before and after t h e t e s t in order t o measure bearing corrosion. T o evaluate t h e antioxidant properties of AN-2 a s e r i e s of concentrations i n t h e range of 0.40 to 1.50% were tested; AN-3 a l s o w a s t e s t e d a t 0.75%. T h e b a s e oil i n t h e s e t e s t s w a s a nonadditive SAE 2 0 blend of solvent-refined neutral and bright sttick having a VI of 109 a n d a viscosity of 372 SUS a t 100°F. 1958

+ 0.75%

AN-2

A t concentrations of 0.75 and 1.5%, AN-2 prevented oil oxidation a n d bearing corrosion a s shown i n Figure 14. At t h e lower concentration of 0.4%. some oxidation occurred, and corrosion w a s higher than is generally considered acceptable. It is probeble that a concentration in the range of 0.40 to 0.75% would give a satisfactory result. T h e t e s t employing AN-3 a t 0.75% concentration showed adequate inhibition, but resulted in higher bearing corrosion than did the use of AN-2 a t this concentration. Both t h e b a s e oil and t h e inhibited o i l s produced pistons k i r t varnish ratings of 9, engine varnish ratings of 47, and total engine sludge and varnish ratings of 93 out of a possible 100. Therefore, the additives did not contribute t o any form of engine dirtiness. ENGINE WEAR STUDIES C h e v r o l e t L-4 Tests. When t h e previously described L-4 t e s t s were conducted, the individual piston rings were weighed before and after the t e s t s in order t o determine ring wear. T h e s e weight measurements revealed that AN-2 substantially reduced ring wear, in a linear relationship with additive concentration, a n d that AN-3 had no effect on t h i s property, as shown in Figure 15. T h e rings from t h e base-oil and AN-3 t e s t s were severely scuffed, while the rings from t h e t e s t s using t h e higher AN-2 concentra. tions showed almost no wear, as evidenced by t h e original tool marks that can b e s e e n in Figure 16. T h e antiwear e f f e c t of AN-2 w a s quite unexpected, because i t s chemical structure d o e s not conform with previous concepts of wear inhibitors. Since AN-2 w a s so effective i n reducing wear under t h e L-4 t e s t conditions, t h e author decided to investigate its antiwear properties further. C h e v r o l e t "Full Throttle" Tests. In order to i n c r e a s e t h e severity of t h e L-4 conditions, t e s t s were performed in t h e Chevrolet engine using the L-4 operating conditions of speed, and sump and jacket temperatures. but substituting full-throttle operation for t h e L-4 part-throttle condition. T h i s change doubled the fuel consumption of t h e engine and increased the brake horsepower from 30 to 70, thereby raising the temperatures i n the ring zone. T h e base o i l i n t h e s e t e s t s w a s t h e same as used i n t h e L-4 t e s t s ; it w a s compared with a blend containing 1.5% of AN-2. T h e results a r e shown i n T a b l e I. When t h e b a s e o i l w a s used, t h e rings were severz-ly scuffed, and t h e wear rate was s e v e n 1 times greater than in t h e L 4 test. AN-2 again demonstrated very effective wear inhibition a s measurz-d by ring-weight l o s s a n d ringgap increase. Satisfactory inhibition of oxidation and CHEMICAL AND ENGINEERING DATA SERIES

335

Table

I.

E f f e c t of AN-2 in "Full T h r o t t l e " Chevrolet T e s t

Base Oil

Oil t 1.5% AN-2

a 48

0.15 0.07

Piston-ring weight l o s s in gramsAverage of 6 rings Top ring Second ring Oil ring

0.26 0.21

Piston-ring gap increase in inches -Average of 6 rings Top ring Second ring Oil ring

0.017 0.012 0.038

0.008 0.004 0.013

Copper-lead bearing corrosion, Average grams per bearing

0.584

0.199

Engine cleanliness Piston skirt varnish Total varnish rating Total engine rating 36-Hour used oil properties Acid number, mg. KOH/gram Increase in viscosity at lOO'F., 7 '

0.05

8.4 45.2 91.2

a 9 46.9 93.3

3.3

1.0

29

13

bearing-corrosion and a measurable improvement in pistonskirt varnish rating were a l s o observed for the oil containing AN-2. C h e v r o l e t FL-2 Tests. The Chevrolet FL-2 ( 7 ) procedure is a low jacket-temperature, high-load t e s t which h a s been used t o evaluate fuel cleanliness. In this 4(rhour test, engine speed is 2500 r.p.m., brake horsepower output i s 45, and the water-jacket inlet temperature is 90°F. Corrosivetype ring and bore wear is usually associated with such a low jacket temperature. T e s t s were conducted using the same fuel and base oil a s in the Chevrolet L-4 test. Two concentrations of AN-2 were employed. A s shown in Figure 17, both additive concentrations of AN-2 showed a large reduction in ring wear when compared with the base oil. However, a lower wear rate was observed a t the lower AN-2 concentration. T h e ring weight l o s s e s were considerably higher in the number one cylinder, and the wear here appeared to b e due t o corrosion. In the other five cylinders, the rings had undergone scuffing, and the antiwear effect of the AN-2 w a s evident. A l l of the engines had high piston-skirt and t o t a l e n g i n e cleanliness ratings of 9.1 and 93-95, respectively, with the AN-2 causing a slight improvement in the sludge ratings. " H o t - R i n g " E n g i n e Tests. In order to evaluate the antiwear properties of AN-2 under other conditions of engine design and operation and with the u s e of a different wearmeasurement technique, a series of t e s t s w a s undertaken in a single-cylinder engine fitted with a radioactive top piston ring. T h e engine was a n overhead-valve prototype of the 1951 Oldsmobile engine. The radioactivity detection system w a s of the flow-monitored type. T h e t e s t s were conducted on a n operating schedule conducive to ring scuffing: 2500 r.p.m. Air flow (supercharger source), 95 lb./hour 0.080 F / A ratio (constant injection s y s t e m ) Jacket water temperature, 180'F. A i r intake temperature, 1 O O O F . Oil sump temperature, 200"F. Ignition cycle, 2.5 minutes a t 30'BTC (max. power) 1 0 seconds a t lOO'BTC (60% power) T e s t time, 20 hours T e s t s per evaluation, three, preceded and followed by baseline t e s t s The fuel was technical-grade isooctane containing 3 ml. of tetraethyllead per gallon as 62 mix and 0.05 wt. % of sulfur a s disulfide oil. Because of the development of very high engine tem-

336

INDUSTRIAL AND ENGINEERING CHEMISTRY

0.1

1 I

I

0

I.5

0.75

0.4

AN-2 CONCN. WT.%

Figure 17. Effect of AN-2 on ring weor in Chevrolet FL-2 test

K K

0 30

w 3

REFERENCE OIL

0.75 W T %

1.5 WT %

AN-2

AN-2

Figure 18. Effect of AN-2 and phenate detergent-antioxidant in radioactive ring engine test Each oil contained 4% of barium phenate

peratures and the need to disperse wear debris for circulation through the detection system, i t w a s necessary to use a detergent and a n antioxidant in t h e s e tests. T h e s e requirements provided a n opportunity to evaluate AN-2 in combination with detergents and in comparison with another antioxidant. The oil in these t e s t s was a blend of a solvent-refined neutral oil (95 VI and 200 SUS a t 100'F.) with 6% of a commercial methacrylate-type VI improver. T h i s formulation, which is typical of blends used in multiple-viscositygrade oils, had a VI of 140 and a viscosity of 300 SUS at 100'F. VOL. 3, NO. 2

In the f i r s t s e r i e s of tests, the b a s e oil contained 4% of a commercial barium phenol sulfide detergent-antioxidant. A comparison w a s made with two concentrations of AN-2 in t h e b a s e oil-phenate blend. As shown in Figure 18, AN-2 concentrations of 0.75 and 1.50% caused a n equal and significant reduction in t h e rate of ring wear. In t h e second s e r i e s of tests, shown in Figure 19, a typical commercial-oil formulation containing a balanced blend of 4% barium sulfonate and 1%zinc dithiophosphate was compared with t h e same base o i l containing 4% barium sulfonate a n d 1.5% AN-2. In effect, t h e AN-2 w a s substituted for t h e zinc dithiophosphate. A significantly lower rate of ring wear w a s observed with the oil containing AN-2 than with the oil containing z i n c dithiophosphate. T h e s e results provide another example of engine conditions and wear measurement technique in which AN-2 effectively minimized abrasive ring wear. They also show that t h i s antiwear effect w a s obtained in the presence of the two most widely used types of commercial motor-oil detergents.

* 0 5

’

5 5

w

o.40c 0

I-

a 0.30

Y (3

z

=2 0.20 PE L

;

0.10

Both AN-2 and AN-3 a r e white crystalline solids. A detailed description of the preparation of AN-2 and AN-3 w a s presented in a recent paper (4). T h e products used in

II.

C e r t a i n P h y s i c a l P r o p e r t i e s of

AN-2

and

AN-2

Figure 19.

Effect of AN-2 and sulfonate detergent in radioactive ring engine test

Both o i l s contained 4% barium sulfonate

AN-3

Hall and Tom Wilkinson t o t h e transmission and multic ylinder-engine studies.

AN-3

LITERATURE CITED

Properties

AN-2

Molecular weight Melting point, OC. Density a t 20°C., grams/ml. Boiling points, OC. a t 40 mm. a t 30 mm. a t 20 mm. a t 10 mm

424.6 154 a 990

263.4 94 0.970

289 280 269 2 50

179 172 163 147

the evaluation s t u d i e s were of a technical grade having a purity of more than 98%. Certain physical properties of t h e s e compounds a r e listed in Table 11. Both AN-2 and AN-3 have a substantial solubility in all types of petroleum oils, even under the most s e v e r e conditions likely to b e encountered in storage. During a 6month storage t e s t in which temperatures as low a s O O F . were encountered, the solubility of AN-2 and AN-3 in a light paraffinic oil did not fall below 1.5 weight %. T h i s represented conditions of minimum solubility s i n c e both of these additives are more soluble in heavier and less paraffinic oils. Acknowledgment

T h e author gratefully acknowledges the contributions of James O’Neill to the laboratory bench-scale testing, Tom Coffield t o the identification of oil oxidation products and synthesis of AN-2 and AN-3, Harold Chalk and Richard Abowd, Jr., t o t h e radioactive engine studies, and C. A.

1958

1.5 WT. 7’

ZINC

DITHIOPHOSPHATE

P H Y S I C A L P R O P E R T I E S OF AN-2 AND A N 3

Table

I .O WT, 7.‘

(1) Am. SOC. Testing Materials, Philadelphia, Pa., ASTM Designation D 943-54. (2) Zbid.. “Standards on Petroleum Products and Lubricants,” D 942-50, November 1954. (3) Calhoun, S. F., 23rd Annual Meeting Natl. Lubricating Grease Inst, Chicago, IlL, 1955. (4) Coffield, T. H., Filbey, A. H., Ecke, G. G., Kolka, A. J., Division of Organic Chemistry, 128th Meeting, ACS, Minneapolis, Flinn., September 1955. (5) Cook, C. D., J. Org. Chem. 18, 261-6 (1953). (6) Coordinating Research Council, “CRC Handbook,” J. J. Little and Ives Co., New York, 1946. (7) Coordinating Research Council Designation FL-2, “ T e s t Procedure for Determining Deposits Formed during LowTemperature Operation. ” (8) Ecke, G. G., Napolitano, J. P., Filbey, A. H., Kolka, A. J., Division of Organic Chemistry, 130th Meeting, ACS, Atlantic City, N. J.. September 1956. (9) Ecke, G. G., Napolitano, J. P., Kolka, A. J., J. Org. Chem. 21, 711 (1956). (10) Hughes, E. C., Bartleson, J. D., Sunday, M. L., Anal. Chem. 21, 737-43 (1949). . . (11) Kolka, A. J., Napolitano, J. P., Ecke, G. G., J. Org. Chem. 21, 712 (19.56). (12) Kolka, A. J., Napolitano, J. P., Filbey, A. H., Ecke, G. G., Division of Organic Chemistry, 130th Fleeting, ACS, Atlantic City, N, J., September 1956. (13) Metro, S. J., J . Am. Chem. Soc, 77, 2901 (1955). (14) Stillson, G. H., Sawyer, D. W., Hunt, C. K., Ibid. 67, 303-7 (1945). (15) Texas Co., Lubrication 40, No. 4 (1954). (16) Wasson, 1. I., Smith, W. M., Ind. Eng. Chem. 45, 197-200 (1953). Received January 18, 1957. Accepted November 22, 1957.

CHEMICAL AND ENGINEERING DATA SERIES

337