TECHNICAL FIELD
[0001] The present invention relates to a lubricating composition for hot-rolling steel.
More particularly, the present invention relates to a lubricating composition by which
a transfer of heat to a work roll from a material to be rolled is prevented and the
effect of reducing the thermal crown of the work roll is attained by incorporating
a specific heat-insulating agent into a base oil or base grease.
BACKGROUND ART
[0002] In the conventional hot-rolling method, only roll-cooling water is used for protecting
a roll, but now a rolling oil is used for reducing the rolling load and decreasing
wear of the roll, and an excellent effect is attached thereby.
[0003] The main object of the conventional lubricant for hot rolling is to reduce wear of
a work roll and improve the roll surface, because the requirement for the quality
of a rolled product is relatively moderate and the thermal crown of the work roll
is not regarded as important. Nevertheless, recently, an increased of the quality
of the product has been demanded, and the effect of reducing the thermal crown of
the work roll, which has an direct adverse influence on the quality of the product,
has become important.
[0004] EP-A-135,932 discloses a lubrication composition for metal forming, which comprises
a condensed phosphoric acid; a sulfur- or chlorine-containing organic compound as
extreme pressure additive; and a solid lubricant such as boron nitride as an additive
when the mold temperature is 300
° C or higher.
[0005] US-A-4,107,058 discloses a composition containing a lithium soap grease and an insoluble
phosphorus composition such a tricalcium phosphate.
DISCLOSURE OF THE INVENTION
[0006] The present invention relates to a lubricant composition for hot-rolling steel, which
is characterized in that a heat-insulating agent is incorporated into a base oil or
base grease. More specifically, it was found that if two specific kinds of heat-insulating
agents, i.e., (A) an inorganic compound which is melted by an absorption of heat at
a temperature lower than 1200°C, and (B) an inorganic powder, selected from silicon
dioxide or silicon nitride, or powder of amorphous carbon, which is not melted or
decomposed at a temperature lower than 1200
°C and has a heat conductivity lower than 0.01 cal/cm.s. ° C at room temperature and
a friction coefficient smaller than 0.7, are incorporated in combination in specific
amounts in the composition, and excellent heat-insulating effect can be attained and
the thermal crown of a work roll can be effectively prevented. The present invention
was completed based on this finding.
[0007] According to the present invention a lubricating composition for hot-rolling steel,
which consists essentially of a base oil or base grease; a combination of heat-insulating
agents (A) and (B), the heat-insulating agent (A) being an inorganic compound which
is melted by an adsorption of heat at a temperature lower than 1200 ° C, the heat-insulating
agent (B) being an inorganic powder, selected from silicon dioxide or silicon nitride,
or powder of amorphous carbon, which is not melted or decomposed at a temperature
lower than 1200 ° C and has a heat conductivity lower than 0.01 cal/cm. s.
° C at room temperature and a friction coefficient smaller than 0.7; an extreme pressure
additive and a solid lubricant, said combination of heat-insulating agents (A) and
(B) being selected from the group consisting of a condensed phosphoric acid salt and
silicon nitride; a condensed phosphoric acid salt and amorphous carbon; a condensed
phosphoric acid salt and silicon dioxide; sodium chloride and silicon nitride; and
sodium silicate and silicon nitride, said extreme pressure additive being selected
from the group consisting of zinc dialkyldithiophosphate, tricresyl phosphate and
sulfurized lard, said solid lubricant being selected from the group consisting of
graphite, molybdenum disulfide, mica and MCA, said heat-insulating agents (A) and
(B) being contained at a weight ratio of from 49/1 to 1/49 and in a total amount of
5 to 50% by weight of the composition.
[0008] When the components (A) and (B) are incorporated in combination, a highest effect
can be attained due to the synergistic action of the two components.
[0009] In the above-mentioned lubricating composition for hot-rolling, by incorporating
an extreme pressure additive and/or a solid lubricant together with the heat-insulating
agents (A) and (B), the lubricating property of the base oil or grease can be further
improved, and the lubricating property, heat-insulating property, storage stability,
working property, and water washing resistance of the base grease can be further improved.
BRIEF DESCRIPTION OF THE DRAWING
[0010] Fig. 1 is a diagram illustrating the method of measuring the contact heat transfer
ratio between metals.
BEST MODE OF CARRYING OUT THE INVENTION
[0011] The surface temperature of a work roll is elevated to about 800 ° C by contact with
a material to be rolled. Most of the conventional lubricants for hot rolling comprise
a mineral oil, an oiliness agent, an extreme pressure additive, and a solid lubricating
agent, in combination, and although the lubricating property is taken into consideration,
an insulation of heat (prevention of transfer of heat to the work roll from the material
to be rolled) is not considered.
[0012] Japanese Unexamined Patent Publication No. 60-6211 teaches that a roll can be protected
by adding a fine powder of an inorganic compound having a melting point lower than
1200
°C under atmospheric pressure, an average particle size smaller than 1 µm, and no corrosive
action on iron and steel including cast iron and cast steel and other metals, and
acting as a substance having a poor heat conductivity to a commercially available
hot-rolling oil (liquid).
[0013] The base oil disclosed in this patent publication is a commercially available hot-rolling
oil (liquid) and is different from the base grease used in the second embodiment of
the present invention. Furthermore, the powder used in the invention of the above-mentioned
patent publication is a powder of an inorganic compound which melts at a temperature
lower than 1200 ° C, and the heat transfer-preventing effect is drastically reduced
after melting.
[0014] In the present invention an inorganic compound melting at a temperature lower than
1200 ° C and an inorganic powder not melting or decomposing at a temperature lower
than 1200°C are used in combination,
[0015] The heat-insulating agent used in the present invention includes (A) an inorganic
compound which is melted by an absorption of heat at a temperature lower than 1200°C
and (B) an inorganic powder which is not melted or decomposed at a temperature lower
than 1200°C, is stable against oxidation and has a heat conductivity lower than 0.01
cal/cm •s• ° C at room temperature (20 °C) and a friction coefficient smaller than
0.7. The inorganic compound (A) which is melted by an absorption of heat at a temperature
lower than 1200 ° C is at least one of condensed phosphoric acid salts such as (KP0
3)
n, (NaP0
3)
n and K
4P
20
7 , sodium silicate, chromic acid salts such as K
2Cr
20
7-, and halides such as NaCI, KCI, KF, KBr and KI. Condensed phosphoric acid salts
and sodium silicate, which have no corrosive action on a rolling mill or a material
to be rolled, are especially preferable.
[0016] The inorganic powder (B), which is not melted or decomposed at a temperature lower
than 1200 ° C, is stable against oxidation and has a heat conductivity lower than
0.01 caI/crn•s• °C at room temperature and a friction coefficient smaller than 0.7,
is at least one of silicon nitride, amorphous carbon, K3PO4 , bentonite, Si0
2 and ZnO. The friction coefficient referred to herein is determined by the pin-on-disk
method (a rod having a diameter of 3 mm and a flat top end is pressed under a load
of 1 kgf against a disk having a diameter of 11 mm, and the disk is slid at a speed
of 0.01 m/s).
[0017] A heat-insulating agent having an average particle size smaller than 50 µm can be
used, but in view of the clearance between the roll and the material to be rolled,
preferably the average particle size of the heat-insulating agent is smaller than
10 µm.
[0018] The reason why better results are obtained when the inorganic compound (A), which
is melted by an absorption of heat at a temperature lower than 1200° C and the inorganic
powder which is not melted or decomposed at a temperature lower than 1200°C and has
a heat conductivity lower than 0.01 cal/cm•s•
° C and a friction coefficient smaller than 0.7 are used in combination, has not been
completely elucidated, but it is considered that the reason is probably as follows.
At the rolling step, the temperature and pressure become high in a roll bite (higher
than 600 ° C and higher than 2000 kgf/cm
2). At this point, the heat-insulating agent (A) is promptly melted by absorption of
heat and prevents heat from being transferred to the work roll from the material to
be rolled. It is known that the heat conductivity of a liquid is, in general, increased
more than that of a powder. Accordingly, it is considered that the heat transfer-reducing
effect of the heat-insulating agent (A) is abruptly decreased by melting. On the other
hand, since the heat-insulating agent (B) is not melted or decomposed even under high-temperature
and high-pressure conditions, the heat-insulating agent (B) is present in the form
of a powder in the roll bite and prevents the work roll from falling in contact with
the material to be rolled, and it is considered that since the powder per se has a
lubricating property, a generation of heat by friction in the roll bite is reduced
by the powder of the heat-insulating agent (B).
[0019] Namely, although the heat-insulating agent (A) has an excellent heat-insulating property,
when the heat-insulating agent (A) is melted at a high temperature, the heat-insulating
property is drastically reduced. On the other hand, since the heat-insulating agent
(B) is not melted or decomposed at a temperature lower than 1200
°C, the heat-insulating agent (B) has a heat-insulating property over a broad temperature
range. Accordingly, if the heat-insulating agent (A) and the heat-insulating agent
(B) are made present at a specific ratio, a lubricating agent having the excellent
effects of both heat-insulating agents (A) and (B) can be obtained.
[0020] Preferably, the heat-insulating agent is added in an amount of 5 to 50% by weight,
especially 10 to 40% by weight. If the amount of the heat-insulating agent is smaller
than 5% by weight, the heat-insulating effect is too low, and if the amount of the
heat-insulating agent is larger than 50% by weight, the viscosity of the lubricant
becomes too high and the oil-supplying property is degraded. Preferably, the ratio
of the heat-insulating agent (A) to the heat-insulating agent (B) is in the range
of 49/1 to 1/49, especially 19/1 to 1/4. This is because, if the proportion of the
heat-insulating agent (A) is reduced, the heat-insulating property is lowered by an
absorption of heat in the roll bite, and if the proportion of the heat-insulating
agent (B) is reduced, the heat-insulating property at high temperature is lowered.
[0021] As the base oil that can be used in the present invention, there can be mentioned
medium and heavy mineral oils such as spindle oil, machine oil, dynamo oil, motor
oil, cylinder oil and bright stock, animal and vegetable oils such as beef tallow,
lard, sperm oil, palm oil, coconuts oil, linseed oil, rice bran oil and soybean oil,
synthetic oils such as esters of fatty acids having 8 to 22 carbon atoms with monohydric
or polyhydric alcohols, a-olefins, polybutene, silicone oils and fluorine oils, and
mixtures of these oils.
[0022] As the base grease that can be used in the present invention, there can be mentioned
lithium soap grease, calcium soap grease, sodium soap grease, aluminum soap grease,
calcium complex grease, polyurea grease and organo-clay grease. Lithium soap grease,
calcium complex grease, polyurea grease and organo-clay grease, which have an excellent
heat resistance, are preferable.
[0023] As the solid lubricant that can be used in the present invention, there can be mentioned
inorganic solid lubricants such as graphite (natural graphite and artificial graphite),
molybdenum disulfide, mica (natural mica and artificial mica), fluorinated graphite,
boron nitride, soft metals (such as gold, silver and copper) and talc, and organic
solid lubricants such as PTFE (polytetrafluoroethylene), MCA (melamine/cyanuric acid
adduct) and phthalocyanine. Graphite (natural graphite and artificial graphite), mica
(natural mica and artificial mica), boron nitride and talc, which have an excellent
heat resistance and oxidation stability at a high temperature and have no substantial
influence on a material to be rolled, are preferably. Preferably the amount added
of the solid lubricant is 0 to 40% by weight, especially 5 to 15% by weight. If the
amount added of the solid lubricant exceeds 40% by weight, the viscosity of the lubricant
becomes too high and the oil-supplying property is reduced.
[0024] As the extreme pressure additive that can be used in the present invention there
can be mentioned sulfur compounds, phosphorus compounds, chlorine compounds and organic
metal compounds. Preferably the amount added of the extreme pressure additive is 0
to 20% by weight, especially 0.5 to 10% by weight. If the amount added of the extreme
pressure additive exceeds 20% by weight, undesired side effects such as an appearance
of a corrosive action and reduction of the stability of the micell structure of the
grease occur.
[0025] The present invention will now be described in detail with reference to the following
examples and comparative examples.
Examples 1 through 16 and Comparative Examples 1 through 11
[0026] A base oil, a base grease, a heat-insulating agent, an extreme pressure additive,
and a solid lubricant were mixed at a mixing ratio shown in Table 1, whereby lubricating
agents of Examples 1 through 16 and Comparative Examples 1 through 11 were prepared.
With respect to each of the so-obtained compositions, the performances were evaluated
according to the test methods described below. The results are shown in Table 1.
A) Lubricating Property Test by Hot Lubricating Property Tester Model E-12
[0027] According to the principle of the hot lubricating property tester Model E-12, both
ends of a test piece were fixed and the test piece induction-heated gripped between
rolls while supplying an oil to the test piece, and a slip lubrication effected. The
friction coefficient and seizure resistance of each lubricant were examined to evaluate
the lubricating property.
[0028] Friction coefficient u. = T/R. W in which T represents a shaft torque, R represents
a roll radius, and W represents a load. The outlines of the tester and the test conditions
are as follows.
a) Type: lubricity tester of two-high type for slip lubricating
b) Roll dimension: 124 mm (diameter ) x 80 mm (length)
c) Roll material: high chromium roll (Hs = 70 - 75)
d) Test piece material: SS-41 [20 mm (height) x 20 mm (width) x 580 mm (length)]
e) Test piece temperature: 400 ° C, 600 ° C and 800 ° C (automatically adjusted)
f) Revolution: 200 rpm
g) Rolling load: 500 to 3000 kgf (the load is increased by 500 kgf at every time)
h) Method of supplying lubricant: applying
B) Rust Prevention Test
[0029]
a) The test piece used at the test (A) was cut to a size of 20 mm x 20 mm x 100 mm.
b) The test piece prepared at a) above has hung under the eaves and allowed to stand
for 2 weeks, and the state of rusting was checked.
o: no rusting
x: extreme rusting
C) Water Washing Resistance Test
[0030]
a) A defatted and weighed steel sheet (SPCC-SD 100 mm x 100 mm x 0.8 mm) was uniformly
coated with 30 ± 3 mg of the lubricant.
b) The steel sheet prepared at a) above was washed with water under the following
conditions, and the weight was measured after the water washing and the residual oil
ratio is determined.
a) Nozzle model number: 1/4 KBF 0865
b) Extrusion rate: 6.4 ℓ/min (extrusion pressure = 2.0 kgf/cm2)
c) Water washing time: 5 seconds (water temperature = 25 ° C)
d) Distance between steel sheet and nozzle: 200 mm
lesidual oil or grease ratio (%) = [(amount of residual oil or grease)/(amount coated
of oil or grease)] x 100
D) Measurement of Contact Heat Transfer Ratio between Metals
[0031]
a) Material of test piece: WT-60 [25 mm (diameter) x 50 mm (length)]
b) Temperature: 780 ° C (high-temperature material), 22 to 30 ° C (low-temperature
material)
c) Thermocouple: CA (0.5 mm) sheath (attachment position = 1.5 mm, 3.0 mm)
d) Heat-insulating material: kao wool
e) Compressive force: 500 kgf/cm2
f) Method of filling sample and thickness:
[0032] As shown in Fig. 1, a high-temperature material 3 was pressed against a low-temperature
material 2 coated with a sample 1, and the contact interface temperature of each sample
and the heat flow flux were reckoned backward from the change of the temperatures
of both materials with a lapse of time after the contact. The cooling law of Newton
was applied in an extended manner to determine the heat transfer coefficient between
the metals. The obtained coefficient was compared with the coefficient obtained when
the sample is not coated, and the heat transfer ratio determined.
[0033] Note, in Fig. 1, reference numeral 4 represents a heat-insulating material and reference
numeral 5 represents a thermocouple.
E) Roll Wearing Quantity Ratio in Actual Rolling Mill
[0034] Eight air spray nozzles (20 mℓ/min•nozzle) were attached to a work roll on the inlet
side of F5 stand (6- stand mill), and about 300 metric tons of an ordinary material
rolled by using nickel grain rolls. The wear quantity was measured and compared with
the wear quantity observed when an oiling agent now available was used.
Explanation of Reference Numerals in the Drawing
[0036]
1: sample
2: low-temperature material
3: high-temperature material
4: heat-insulating material
5: thermocouple
1. A lubricating composition for hot-rolling steel, which consists essentially of
a base oil or base grease; a combination of heat-insulating agents (A) and (B), the
heat-insulating agent (A) being an inorganic compound which is melted by an adsorption
of heat at a temperature lower than 1200 ° C, the heat-insulating agent (B) being
an inorganic powder, selected from silicon dioxide or silicon nitride, or powder of
amorphous carbon, which is not melted or decomposed at a temperature lower than 1200°C
and has a heat conductivity lower than 0.01 cal/cm. s. ° C at room temperature and a friction coefficient smaller than 0.7; an extreme pressure
additive and a solid lubricant, said combination of heat-insulating agents (A) and
(B) being selected from the group consisting of a condensed phosphoric acid salt and
silicon nitride; a condensed phosphoric acid salt and amorphous carbon; a condensed
phosphoric acid salt and silicon dioxide; sodium chloride and silicon nitride; and
sodium silicate and silicon nitride, said extreme pressure additive being selected
from the group consisting of zinc dialkyldithiophosphate, tricresyl phosphate and
sulfurized lard, said solid lubricant being selected from the group consisting of
graphite, molybdenum disulfide, mica and MCA (melamine/cyanuric acid adduct), said
heat-insulating agents (A) and (B) being contained at a weight ratio of from 49/1
to 1/49 and in a total amount of 5 to 50% by weight of the composition.
2. A lubricating composition for hot-rolling steel according to claim 1, wherein the
base oil is a member selected from the group consisting of spindle oil, machine oil,
dynamo oil, motor oil, cylinder oil, bright stock, beef tallow, lard, sperm oil, palm
oil, coconut oil, linseed oil, rice bran oil, soybean oil, esters of fatty acids having
8 to 22 carbon atoms with monohydric and polyhydric alcohols, a-olefins, polybutene,
silicone oils and fluorine oils.
3. A lubricating composition for hot-rolling steel according to claim 1, wherein the
base grease is a member selected from the group consisting of lithium soap grease,
calcium soap grease, sodium soap grease, aluminum soap grease, calcium complex grease,
polyurea grease and organo-clay grease.
4. A lubricating composition for hot-rolling steel according to claim 1, wherein the
solid lubricant is a member selected from the group consisting of natural graphite,
artificial graphite molybdenum disulfide, natural mica, artificial mica, boron nitride,
soft metals, talc, polytetrafluoroethylene, melamine/cyanuric acid adducts and phthalocyanine.
5. A lubricating composition for hot-rolling steel according to claim 1, wherein the
extreme pressure additive is a member selected from the group consisting of sulfur
compounds, phosphorus compounds, chlorine compounds and organic metal compounds.
1. Schmiermittelzusammensetzung zum Warmwalzen von Stahl, die im wesentlichen besteht
aus: einem Basisöl oder Basisfett; einer Kombination von wärmedämmenden Mitteln (A)
und (B), wobei das wärmedämmende Mittel (A) eine anorganische Verbindung ist, die
durch Wärmeadsorption bei einer Temperatur von weniger als 1200°C schmilzt, das wärmedämmende Mittel (B) ein anorganisches Pulver ist, das aus Siliciumdioxid
oder Siliciumnitrid oder Pulver von amorphem Kohlenstoff ausgewählt ist, das bei einer
Temperatur von weniger als 1200 ° C nicht schmilzt oder zersetzt wird und ein Wärmeleitvermögen von weniger als 0,01
caI/crn•s• °C bei Raumtemperatur und einen Reibungskoeffizienten von weniger als 0,7 aufweist;
einem EP-Additiv und einem festen Schmiermittel, wobei die Kombination aus wärmedämmenden
Mitteln und (A) und (B) aus der Gruppe ausgewählt ist, die aus einem kondensierten
Phosphorsäuresalz und Siliciumnitrid; einem kondensierten Phosphorsäuresalz und amorphem
Kohlenstoff; einem kondensierten Phosphorsäuresalz und Siliciumdioxid; Natriumchlorid
und Siliciumnitrid; und Natriumsilicat und Siliciumnitrid besteht; das EP-Additiv
aus der Gruppe ausgewählt ist, die aus Zinkdialkyldithiophosphat, Tricresylphosphat
und geschwefeltem Schmalz besteht, das feste Schmiermittel aus der Gruppe ausgewählt
ist, die aus Graphit, Molybdändisulfid, Glimmer und MCA (Melamin/Cyanursäure-Addukt)
besteht, und die wärmedämmenden Mittel (A) und (B) in einem Gewichtsverhältnis von
49/1 bis 1/49 und in einer Gesamtmenge von 5 bis 50 Gew.-% der Zusammensetzung enthalten
sind.
2. Schmiermittelzusammensetzung zum Warmwalzen von Stahl nach Anspruch 1, wobei das
Basisöl eine Verbindung ist, die aus der Gruppe ausgewählt ist, die aus Spindelöl,
Maschinenöl, Dynamoöl, Motoröl, Zylinderöl, Brightstock, Rindertalg, Schmalz, Spermöl,
Palmöl, Kokosnußöl, Leinsamenöl, Reisöl, Sojabohnenöl, Estern von Fettsäuren mit 8
bis 22 Kohlenstoffatomen mit einwertigen und mehrwertigen Alkoholen, a-Olefinen, Polybuten,
Siliconölen und Fluorölen besteht.
3. Schmiermittelzusammensetzung zum Warmwalzen von Stahl nach Anspruch 1, wobei das
Basisfett eine Verbindung ist, die aus der Gruppe ausgewählt ist, die aus Lithiumseifenfett,
Calciumseifenfett, Natriumseifenfett, Aluminiumseifenfett, Calciumkomplexfett, Polyharnstoffett
und Organopolysilicatfett besteht.
4. Schmiermittelzusammensetzung zum Warmwalzen von Stahl nach Anspruch 1, wobei das
feste Schmiermittel eine Verbindung ist, die aus der Gruppe ausgewählt ist, die aus
natürlichem Graphit, künstlichem Graphit, Molybdändisulfid, natürlichem Glimmer, künstlichem
Glimmer, Bornitrid, weichen Metallen, Talkum, Polytetrafluorethylen, Melamin/Cyanursäure-Addukten
und Phthalocyanin besteht.
5. Schmiermittelzusammensetzung zum Warmwalzen von Stahl nach Anspruch 1, wobei das
EP-Additiv eine Verbindung ist, die aus der Gruppe ausgewählt ist, die aus Schwefelverbindungen,
Phosphorverbindungen, Chlorverbindungen und Organometallverbindungen besteht.
1. Composition lubrifiante pour le laminage à chaud de l'acier, consistant essentiellement
en une huile de base ou une graisse de base; une combinaison d'agents isolants thermiques
(A) et (B), l'agent isolant thermique (A) étant un composé inorganique que l'on fait
fondre par adsorption de chaleur à une température inférieure à 1200 ° C, l'agent isolant thermique (B) étant une poudre inorganique, choisie parmi le dioxyde
de silicium ou le nitrure de silicium, ou une poudre de carbone amorphe, qui ne fond
pas ni ne se décompose à une température inférieure à 1200 ° C et a une conductivité thermique inférieure à 0,01 cal/cm.s. ° C à la température ambiante et un coefficient de frottement inférieur à 0,7; un additif
d'extrême pression et un lubrifiant solide, ladite combinaison d'agents isolants thermiques
(A) et (B) étant choisie dans le groupe constitué par un sel d'acide phosphorique
condensé et le nitrure de silicium; un sel d'acide phosphorique condensé et le carbone
amorphe; un sel d'acide phosphorique condensé et le dioxyde de silicium; le chlorure
de sodium et le nitrure de silicium; et le silicate de sodium et le nitrure de silicium,
ledit additif d'extrême pression étant choisi dans le groupe constitué par le dialkyldithiophosphate
de zinc, le phosphate de tricrésyle et la graisse sulfurée, ledit lubrifiant solide
étant choisi dans le groupe constitué par le graphite, le disulfure de molybdène,
le mica et le MCA (produit d'addition mélamine/acide cyanurique), lesdits agents thermiquement
isolants (A) et (B) étant contenus en un rapport pondéral de 49/1 à 1/49 et en une
quantité totale de 5 à 50% en poids de la composition.
2. Composition lubrifiante pour le laminage à chaud de l'acier selon la revendication
1, dans laquelle l'huile de base est un membre choisi dans le groupe constitué par
l'huile minérale pour broches, l'huile pour machine, l'huile de dynamo, l'huile moteur,
l'huile pour cylindres, le bright stock, le suif de boeuf, le saindoux, l'huile de
spermaceti, l'huile de palme, l'huile de coco, l'huile de lin, l'huile de son de riz,
l'huile de soja, les esters d'acides gras ayant de 8 à 22 atomes de carbone avec les
alcools monohydriques et polyhydriques, les a-oléfines, le polybutène, les huiles
de silicone et les huiles de fluor.
3. Composition lubrifiante pour le laminage à chaud de l'acier selon la revendication
1, dans laquelle la graisse de base est un membre choisi dans le groupe constitué
par la graisse de savon de lithium, la graisse de savon de calcium, la graisse de
savon de sodium, la graisse de savon d'aluminium, la graisse de complexe de calcium,
la graisse de polyurée et la graisse d'argile organique.
4. Composition lubrifiante pour le laminage à chaud de l'acier selon la revendication
1, dans laquelle le lubrifiant solide est un membre choisi dans le groupe constitué
par le graphite naturel, le graphite artificiel, le disulfure de molybdène, le mica
naturel, le mica artificiel, le nitrure de bore, les métaux doux, le talc, le polytétrafluoroéthylène,
les produits d'addition mélamine/acide cyanurique et la phtalocyanine.
5. Composition lubrifiante pour le laminage à chaud de l'acier selon la revendication
1, dans laquelle l'additif d'extrême pression est un membre choisi dans le groupe
constitué par les composés de soufre, les composés de phosphore, les composés de chlore
et les composés organo-métalliques.