DE2460261A1 - ABSCHRECKOEL AND ITS USES - Google Patents

Description

SHELL INTERNATIONAL RESEARCH MAATSCIIAPPIJ B.V. The Hague, Netherlands

"Quenching Oil and Its Uses"

Priority: December 21, 1973, V.St.A., No. 427,204

The invention relates to a quenching oil which does not impair the purity and gloss of the surface of the metal to be hardened. The invention also relates to the use of the aforementioned quenching oil for hardening ferrous materials.

The hardening of ferrous materials by heating to temperatures above 374 ° C and subsequent rapid cooling is well known. The cooling level used in hardening is called "quenching". It is also known that faster quenching results in increased hardness of the metal leads. As quenching liquids are usually

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Hydrocarbon oils and especially mineral oils are used. As such, a few mineral oils have a high rate of heat exchange and can therefore be used as quenching oils without additives. Generally pure form However, mineral oils are not a satisfactory quenching medium because of the slow initial cooling. It is believed, that the significantly different quenching speeds of the few suitable as quenching oils and the most other oils are due to the presence or absence of very low concentrations of oil constituents. Therefore, in the development of quenching oils, attempts are made to reduce the hydrocarbon oils by adding certain Modify additives. According to the current state of the art, there are many different additives for the aforesaid Purpose used (see e.g. U.S. Patent No. 3,729,417). Such additives to improve the cooling rate are e.g. ash-forming materials, such as oil-soluble alkali metal and / or alkaline earth metal petroleum sulfonates, e.g. calcium, Sodium or barium sulfonates. These materials leave an "ash" or debris on the metal that can reduce the shine or shine affects the cleanliness of the metal surface. It is difficult to wipe these deposits off the metal surface or remove. The two most important properties of one

achievable

Quenching oil is the degree of hardness and the purity of the surface of the quenched material. The problem is that quenching oils permitting high quenching speeds lead to a good degree of cure, usually unclean

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or mottled metal surfaces. In the DT patent application P 24 46 011.5 describes a quenching oil that solves this problem through a content of effective additives that enable rapid heat exchange between the metal and the oil during heat treatment, such as when hardening steel and result in an easily removable flaky deposit on the surface of the heat treated metal. It would be however, it is advantageous to allow high quenching speeds To have quenching oil available that leads to shiny surfaces when quenching ferrous materials.

The invention accordingly relates to a quenching oil that improves the purity and gloss of the surface of the metal to be hardened does not affect a mineral oil with a high heat exchange rate, measured as GMC magnetic quenchometer time, from about 9 to 15 seconds, and about 0.1 to 10 weight percent of a mono- (polyisobutenyl) -substituted Succinic acid imides of tetraethylene pentamine in which the polyisobutenyl substituent has a molecular weight of from about 750 to about 5000.

By using the quenching oil according to the invention, methods for quenching metals and in particular of Improve steel.

The invention accordingly further relates to the use of the invention Quenching oil for quenching ferrous. Metals, whereby the metal to be treated is heated to higher

A f \ Q ß 9 7 / η R ς Q

ratures heated and then to increase the hardness of the treated Metal is rapidly cooled in the quenching medium.

The base mineral oil, which in addition to the additive is a critical component of the invention, must not only be thermally

be stable
sch / and anti-oxidation properties that the

meet the desired requirements in a quenching oil,
but also a high rate of heat exchange
exhibit. The high heat exchange rate required for the mineral oil component of the quenching oil according to the invention can be defined as the quenching time measured by means of the “GMC Magnetic Quenchometer Test”. This test is based on

that metals when heated to above a critical value
(Curie point)

/ lying temperatures their magnetic properties

lose it and put it back when it cools down. Polished nickel balls that are preheated to 885 C in a muffle furnace
are past a photoelectric cell in
dropped a measured volume of oil placed in a magnetic field. When the nickel ball cools to its Curie point, which is around 354.44 C for pure nickel, it regains its magnetic properties and is attracted by a magnet. One switched on by the photoelectric cell when the nickel ball fell past
electric clock will stop automatically when the ball is attracted to the magnet. This will determine the quench time of the sample or oil being tested. The lower the determined quenching time, ie the fewer seconds until

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If the ball is attracted by the magnet, the greater the quenching speed of the quenching oil and its Cooling effect. According to the invention, the mineral oil component must be a The quenching time measured by the GMC Magnetic Quenchometer Test described above is from about 9 to about 15 seconds exhibit. Oils with a quench time in this range are known as rapid quenching oils. As discussed above, some equivalent mineral oils have high levels as such Heat exchange rates and are therefore suitable without additives as a sniff quenching mineral oil component of the invention Quenching oil. In addition, certain mineral oil components are suitable for a quenching oil according to the invention ash-free additives to improve the quenching speed

how
mineral oils containing dience, / they have been described in the aforementioned DT patent application P 24 46 011.5. In this patent application a quenching oil with an improved cooling rate is described which consists essentially of a mineral oil having a viscosity of about 15 to about 200 SUS at 37.8 C and an aromatic content of 8 to 60 percent and in which critical amounts of about 0.005 up to approximately 0.04 percent by weight of a vicinally substituted 2-mercaptothiazole with two hydrocarbon radicals or a divalent hydrocarbon radical with preferably 1 to 6 carbon atoms are dissolved. In general, a quick-quenching mineral oil alone or a quick-quenching additive to improve the quenching rate of the base material can be used as the mineral oil component for the quenching oil according to the invention.

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ORIGINAL BATHROOM

Mineral oil containing mineral oil can be used, the mineral oil component according to the invention described above a quenching time measured by the GMC Magnetic Quenchometer test from about 9 to about 15 seconds.

The required for the purity and gloss of the surface of the metal to be hardened quenching oil, critical and specific detergent can be described as a mono (polyisobutenyl) -substituted succinic acid imide of tetraethylene pentamine in which the polyisobutenyl substituent has a molecular weight of about 700 to about 5000, and preferably from about 2000 to about 4000. The required concentration of mono (polyisobutenyl succinic acid additive for the quenching oil of the invention is from about 0.1 to about 10.0 percent by weight based on the amount of the quenching oil of the invention. Preferably 0.5 to 5.0 percent by weight of the mono (polyisobutenyl) succinic acid additive _and especially 2.5 percent of the additive is used.

The quenching oil of the present invention which is the above Contains mono (polyisobutenyl) succinic acid imide additives, can with regard to its oxidation stability by adding e.g. phenolic and amine antioxidants be improved.

The example illustrates the invention.

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BAD ORKSJNAL

example

The effect of the mineral oil component alone, and the one below specified concentrations of additives containing mineral oil component as the purity and gloss of the Rapid quenching oil that does not adversely affect the surface of the metal to be hardened is used in a test of the quenching oil by means of of a GMC magnetic quenchometer test experiment. This The experiment was described above for the determination of the quenching time. The effect is also shown in this test of a quenching oil was determined for the gloss and cleanliness of the surface of the quenched material in the following manner. The time required to determine the quenching time (GMC quenching time, seconds) The polished nickel balls used are determined after the quenching time obtained, taking into account the appearance of the quenched nickel balls were evaluated for their surface cleanliness. The value for purity and shine is characteristic of the effect that does not impair the purity and gloss of the surface of the metal to be hardened of the quench oil, and this rating is expressed using the letters "A" through "E", inclusive, as described below:

A = no deposits or traces of deposits B = traces of deposits to light deposits C = light deposits
D = medium deposits
E = significant deposits

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- R -

In the practice of large-scale cutting operations, the quenching oil is moved or stirred during quenching, and then the quenched material parts are washed or wiped several times to remove the remaining oil. In order to better reflect the large-scale operation and to obtain results regarding the effectiveness of the additive in the production of a shiny or pure metal surface better reproduced, is the one described above GMC Magnetic Quenchometer test experiment one modification stage downstream and used together with the aforementioned test. According to the modified test, an in Standard GMC Magnetic Quenchometer test sphere preheated to 885 ° C in a muffle furnace (i.e., a polished nickel ball) is dropped into 260 g of the quenching oil to be tested and the oil Vigorously stirred for 15 minutes. The ball is then determined according to the above-described values "A" to "E" in terms of its surface deposits rated. The ball is then wiped with a wipe and assessed again as described above.

In the following Table I, the values and results are given in Experiment 1 when using a mineral oil component alone shown without detergent additives. In experiments 2 and 3, the effect of the additive according to the invention shown containing quenching oils, while in experiments 4 to 7 not according to the invention additives containing quenching oils are reproduced for the sake of comparison in order to show

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BATH ORIGINAL

that similar detergents or additives having a similar chemical make-up are far less effective at faster quenching that does not impair the purity and luster of the surface of the metal than that of the present invention Are quenching oil. The as the base oil in the following The mineral oil component used in Table I has the following composition:

100 neutral Volume percentage HVI 150 Brightstock ⁷⁸ \ HVI

Weight percent

Low viscosity mineral oil

(40 to 47 SUS at 37.3 ° C)

R Ionol antioxidant

(2,6-di-tert-butyl-4-methyl-phenol)

99.75

0.25

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attempt

Table I.

GMC magnetic quenchometer test

Quenching time, sec

1. Base oil alone 11.8

2. Base oil + 5% by weight mono (polyisobutenyl) succinic acid imide v. Tetraethylene pentamine; Mol.wt. d.Polyisobutenyl group from approx. 700 to approx. 5000 12.0

3. Base oil + 5% by weight mono (polyisobutenyl) succinic acid imide v '.

Tetraethylene pentamine; Mole weight d.Polyisobutenyl group from 2000 to approx. 4000 12.6

4. Base oil + 5 wt .-% polyisobutenyl succinic acid imide, which is chemically with a reactive carbonyl compound has been further modified

is 11.9

5. Base oil + 5% by weight bis (polyisobutenyl) succinic acid imide of tetraethylene pentamine 11.4

6. Base oil + 5% by weight of a polyisobutenylsuccinic acid diester a polyol 11.2

7. Base oil + 5% by weight Mannich base- (aldehyde-Mi η) - it detects that approx. 0.3% by weight

Boron contains 13.3

Assessment d. Shine d. Surface d. deterred

Metal

Modified test evaluation of the gloss of the surface of the quenched metal

Before / after wiping

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Claims (5)

Claims 1. Quenching oil that improves the purity and gloss of the surface of the metal to be hardened, containing a mineral oil having a high heat exchange rate, measured as GMC Magnetic Quenchometer Time, from about 9 to about 15 seconds, and about 0.1 to 10 weight percent of a mono (polyisobutenyl) substituted succinic acid imide of Tetraethylene pentamine in which the poly visobutene substituent has a molecular weight of from about 750 to about 5000. 2. Quenching oil according to claim 1, characterized in that it is a mineral oil component with a high heat exchange rate which has a viscosity of about 15 to about 200 SUS at 37.8 ° C and an aromatics content of 8 to 60 percent and about 0.005. up to about 0.04 weight percent of one having two hydrocarbon radicals or contains a divalent hydrocarbon radical with 1 to 6 carbon atoms vicinally substituted 2-mercaptothiazole. 3. Quenching oil according to claim 1 or 2, characterized in that it contains about 0.5 to about 5 weight percent succinic acid imide additive contains. 4. quenching oil according to claim 1 to 3, characterized in that that it is a succinic acid imide additive having a polyisobutenyl group with a molecular weight of about 2000 to 509827/0659 contains about 4000. 5. Use of the quenching oil according to claim 1 to 4 for hardening ferrous metals, in which a to be treated Metal heated to elevated temperatures and then rapidly placed in a quenching medium to increase the hardness of the metal is cooled. 509827/06 5