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The viscosity-pressure-temperature dependence of mineral oils (in German)
401
LITERATUREANDCURRENTEVENTS
Authors’ Study of the Thermal
Abstracts
Behaviour of Diesel Engine Oils (in French)
M. MACNABANDM. A. DE GOLDLIN*, SociCtC ANTAR (Paris). The bench test makes it possible to study the behaviour of a lubricant in operation. But, since it is long and costly, it must itself be preceded by simpler tests which enable direct researches to be carried out. It is for this purpose that ANTARlaboratories developed a coking bench where the oil undergoes a similar aging to that observed in a diesel engine. When sprayed onto a heated metal surface, it drips together with condensates into a cold beaker and the process is then repeated, following the same cycle as the lubricant does in the engine, passing from the hot cylinder walls to the cold sump. The adopted device is flexible enough to enable operation under various temperatures, and accurate enough to provide reproducible results. The coke and varnishes produced on the hot surface, both by the liquid oil and by its vapours, are examined, as are the oil characteristics at the end of the test. Thus, curves are obtained of, for example, coke weight versus time or acid index versus time at various temperatures. The optimum composition for a mineral oil could first be determined, and then the improvement of its thermal strength resulting from the addition of various dopes. The comparison of the curves of various lubricants obtained on the coking bench, and of the PETTER engine data, showed a clear relationship between both sets of results. The value of the coking bench as a research instrument was thus demonstrated. Wear, 3 (1960) 401
The Viscosity-Pressure-Temperature
Dependence of Mineral Oils (in German)
E. Kuss (Institut fur Erdolforschung, Hannover, Germany) - Materia@rGfung, (1960) rSg-rg7;
z (6)
(9 fig., 4 tables, 35 ref.).
Owing to the complexity of multicomponent mineral-oil systems of unknown molecular structure, it is much more difficult to predict the technically important dependence of viscosity upon pressure for lubricating oils than it is for chemically well-defined substances. Difficulties are enhanced when oil additives are present. A considerable number of lubricating oils, some of widely varying composition, were investigated up to 2000 atmospheres, with the following results: (a) Characterization of the oil composition, for instance with the aid of Waterman’s method, is not sufficient for determining viscosity-pressure behaviour. At least * Lecture given to the “SociBt.5 des In&nieurs de 1’Automobile”. For information and reprints write to: ANTAR, 4 Rue LBon Jost, Paris 17; c/o Direction Technique & Etudes, Section Constructeurs et Documentation. WW’, 3 (1960) 401-402
$12
LITERATUREAKDCURRENTEVENTS
the degree structural
of branching
should
be additionally
accounted
for by means
of a
coefficient.
(b) The relation between the pressure coefficient tion was shown not to be sufficiently
of viscosity
accurate
and the energy of activa-
for predicting
pressure dependence
on viscosity. (c) However,
a prediction
an accuracy
of the viscosity-pressure
of about 5-7%,
values of the Waterman The presence additional
of additives,
correction
viscosity-pressure matically.
can be derived with
is used in connection
with certain
analysis. such as lead-naphthenate,
of the value of density. coefficient
The new method of predicting
must be accounted
In this way great
with temperature
will be taken
viscosity-pressure
was checked by means of our own experimental ASME
coefficient
if the aniline-point
for by an
variations
into
of the
account
behaviour
auto-
of mineral oils
data as well as of the results of the
project.
(See also: E. KUSS:Z.
anger. Phys., IO (1958) 566-575.) Wear,
3 (1960)
401-402
Wear Research and Rheology (in German)
G. SALOMON
(Centraal
fung,I (x1/12)(1959)
Laboratorium 385-390;
should
between
bulk properties
Some of the concepts used in technological
The theory
of friction
be considered
between
primary
Although yet possible
is then used as a starting separately.
processes
maximum to predict
in friction
rubbers
and fibres is briefly
outlined.
that the wear resistance
and temperature,
is determined
point. Elastic
of
and plastic
approaches
processes
give a correlation
and in wear. of rubbing
properties
and wear resistance
work on wear are first explained.
statistical
all the consequences
and of rheological
technology
Recent
temperatures
thermal
Materialfwii-
Delft, The Netherlands)
(4 fig.; 51 ref.).
A study is made of the correlation materials.
T.N.O.,
surfaces
can be calculated,
of frictional
on the ultimate
of
of abrasives,
from recent
under extreme
by their thermal
The influence
wear resistance
It can be concluded
of materials,
heating.
it is not
advances
conditions
in
of pressure
and also by their rheological
prop-
erties. Wear,
Stick-Slip
H. CATLING
Friction as a Cause of Torsional Vibration
(Institution
of MechanicalEngrs.,
3 (1960)
402
in Textile Drafting Rollers
London). Advance copy No. 26/59 (r96o)
7 pp. ; (g fig., I table, 7 ref .) Torsional
vibration
of long rollers stimulated
by stick-slip
frictional Weur,
behaviour 3 (1960)
con-
402-403
LITERATUREANDCURRENTEVENTS
Authors’ Study of the Thermal
Abstracts
Behaviour of Diesel Engine Oils (in French)
M. MACNABANDM. A. DE GOLDLIN*, SociCtC ANTAR (Paris). The bench test makes it possible to study the behaviour of a lubricant in operation. But, since it is long and costly, it must itself be preceded by simpler tests which enable direct researches to be carried out. It is for this purpose that ANTARlaboratories developed a coking bench where the oil undergoes a similar aging to that observed in a diesel engine. When sprayed onto a heated metal surface, it drips together with condensates into a cold beaker and the process is then repeated, following the same cycle as the lubricant does in the engine, passing from the hot cylinder walls to the cold sump. The adopted device is flexible enough to enable operation under various temperatures, and accurate enough to provide reproducible results. The coke and varnishes produced on the hot surface, both by the liquid oil and by its vapours, are examined, as are the oil characteristics at the end of the test. Thus, curves are obtained of, for example, coke weight versus time or acid index versus time at various temperatures. The optimum composition for a mineral oil could first be determined, and then the improvement of its thermal strength resulting from the addition of various dopes. The comparison of the curves of various lubricants obtained on the coking bench, and of the PETTER engine data, showed a clear relationship between both sets of results. The value of the coking bench as a research instrument was thus demonstrated. Wear, 3 (1960) 401
The Viscosity-Pressure-Temperature
Dependence of Mineral Oils (in German)
E. Kuss (Institut fur Erdolforschung, Hannover, Germany) - Materia@rGfung, (1960) rSg-rg7;
z (6)
(9 fig., 4 tables, 35 ref.).
Owing to the complexity of multicomponent mineral-oil systems of unknown molecular structure, it is much more difficult to predict the technically important dependence of viscosity upon pressure for lubricating oils than it is for chemically well-defined substances. Difficulties are enhanced when oil additives are present. A considerable number of lubricating oils, some of widely varying composition, were investigated up to 2000 atmospheres, with the following results: (a) Characterization of the oil composition, for instance with the aid of Waterman’s method, is not sufficient for determining viscosity-pressure behaviour. At least * Lecture given to the “SociBt.5 des In&nieurs de 1’Automobile”. For information and reprints write to: ANTAR, 4 Rue LBon Jost, Paris 17; c/o Direction Technique & Etudes, Section Constructeurs et Documentation. WW’, 3 (1960) 401-402
$12
LITERATUREAKDCURRENTEVENTS
the degree structural
of branching
should
be additionally
accounted
for by means
of a
coefficient.
(b) The relation between the pressure coefficient tion was shown not to be sufficiently
of viscosity
accurate
and the energy of activa-
for predicting
pressure dependence
on viscosity. (c) However,
a prediction
an accuracy
of the viscosity-pressure
of about 5-7%,
values of the Waterman The presence additional
of additives,
correction
viscosity-pressure matically.
can be derived with
is used in connection
with certain
analysis. such as lead-naphthenate,
of the value of density. coefficient
The new method of predicting
must be accounted
In this way great
with temperature
will be taken
viscosity-pressure
was checked by means of our own experimental ASME
coefficient
if the aniline-point
for by an
variations
into
of the
account
behaviour
auto-
of mineral oils
data as well as of the results of the
project.
(See also: E. KUSS:Z.
anger. Phys., IO (1958) 566-575.) Wear,
3 (1960)
401-402
Wear Research and Rheology (in German)
G. SALOMON
(Centraal
fung,I (x1/12)(1959)
Laboratorium 385-390;
should
between
bulk properties
Some of the concepts used in technological
The theory
of friction
be considered
between
primary
Although yet possible
is then used as a starting separately.
processes
maximum to predict
in friction
rubbers
and fibres is briefly
outlined.
that the wear resistance
and temperature,
is determined
point. Elastic
of
and plastic
approaches
processes
give a correlation
and in wear. of rubbing
properties
and wear resistance
work on wear are first explained.
statistical
all the consequences
and of rheological
technology
Recent
temperatures
thermal
Materialfwii-
Delft, The Netherlands)
(4 fig.; 51 ref.).
A study is made of the correlation materials.
T.N.O.,
surfaces
can be calculated,
of frictional
on the ultimate
of
of abrasives,
from recent
under extreme
by their thermal
The influence
wear resistance
It can be concluded
of materials,
heating.
it is not
advances
conditions
in
of pressure
and also by their rheological
prop-
erties. Wear,
Stick-Slip
H. CATLING
Friction as a Cause of Torsional Vibration
(Institution
of MechanicalEngrs.,
3 (1960)
402
in Textile Drafting Rollers
London). Advance copy No. 26/59 (r96o)
7 pp. ; (g fig., I table, 7 ref .) Torsional
vibration
of long rollers stimulated
by stick-slip
frictional Weur,
behaviour 3 (1960)
con-
402-403