DE2002333C - Electrical contact grease - Google Patents

Description

3 4

serve to prevent the temperature rise in an amount less than 10 percent by weight and the wear and tear of the contact, resulting in a contact grease with poor homogeneity. Burning of the fat by arcing. If the amount of the mixture of metal soaps and at the same time act as a lubricant. less than about 10 weight percent in the fat A better result can be achieved by giving a value of 5, if the resulting contact grease is too soft, at least one of the following compounds in order to be dimensionally stable. A quantity of the mixture used: trichlorodiphenyl, tetrachlorodiphenyl, pen- of more than 20 percent by weight results in the tachiordiphenyl, hexachlorodiphenyl, Polychlo'rtriphe - on the other hand, a contact grease that is too hard. nyl. Pentachlorodiphenyloxid, Pesuachlorphenylben- A contact grease according to the invention can by zoate, hexachlorodiphenyl methane and pentachlorodio addition of an antioxidant and / or rust phenyl ketone. The best results will be improved in- in- inhibitors. The preferred antidotes with trichlorodiphenyl, tetrachlorodiphen oxidizing agents are n-butyl-p-aminophenol. Di-secnyl, Hexachlorodiphenyl and polychlorotriphenyl erbutyl - ρ - phenylenedi <imine, 4,4 '- tetramethyldiamino. diphenylmethane, ct-naphthylamine, η, η'-disalicylidene

When the chlorinated aromatic hydrocarbon 15 is 1,2-propylenediamine, 2,6-di-tert. - butylpheaol.

or the derivative thereof in an amount of less than 2,4-dimethyl-6-tert. - butylphenol, 2,6-di-part.

a! s about 7 percent by weight are present, increases butyl - ρ - cresol, 4,4 '- methylene - bis - (2.6-di-tert.-

the temperature rise of the contact while butylphenol). 2,2 '- methylene - bis - (4-methyl-6-tert.-

an amount vj, \ more than about 15 percent by weight butylphenol), 4,4 '- butylidene - bis - (3-methyl-6-tert.-

the production of a contact with good fat homo- ia butylphenol). The preferred rust inhibitors are

genicity made difficult. Sorbitan monooleate, a salt of the dinonylnaphthalene

The paraffinic misulfonates and \ - (2-carboxyphenoxy) stearic acid used according to the invention. Mineral oil can be either a pure paraffinic mineral oil. The amount of antioxidant is preferred as well as an impure paraffinic mineral oil, which is 0.01 to about 3 percent by weight, which is a small amount, e.g. B. up to 30 percent by weight. 25 indicates 0.01 to 3 percent by weight of the antioxidant aromatic and / or naphthenic mineral oil and about 97 to 99.99 percent by weight of the contains. The paraffinic mineral oil has contact fat. The amount of the rust inhibitor is preferably a viscosity from 40 to 180 Centistck sth 0.01 to ^f a 4 percent by weight rust inhibitor at 37.8 ° C and an aniline point above 90 to be about 96 to 99.99 weight percent of the contact-ASTM D611-55 & (American Society for Testing 30 fat.
Materials). A mixture of paraffinic mineral oil,

Barric soaps, lithium soaps and aluminum, a mixture of metal soaps, chlorinated aluminum soaps, including those containing matic hydrocarbons or their derivatives containing an aliphatic fatty acid residue, can be used. Their formulas with or without antioxidants and RostinhichemLchen formulas are given by Ba (RCOO) ₂ , 35 bitor is heated to 200 ~ 250 ° C in order to _{reproduce a homo-Li (RCOO) or Al (RCOO) 3} , in which gene liquid is produced, and then on space R is an alkyl radical. These formulas are designed to be temperature cooled. The g cooled mixture, however, does not apply the invention to the pure substances by means of one of the usual methods, e.g. B. on a limit, but also contaminated substances three-roller mill, ground and then encompassed, which contain the unavoidable reduced pressure of a removal of air foam impurities. For example, this includes subject.

commercially available Al (RCOO) ₃ an amount of The fats obtained are smooth and buttery in terms of their Konweniger than 20 percent by weight of Al (OH) (RCOO) ₂ and have excellent mechanical and thermal stability for the production of a contact grease , the invention can be used. The radical R in the above 45 The following examples are intended to illustrate the invention chemical formulas should preferably 12 to. Have 20 carbon atoms. The particularly preferred barium, lithium and aluminum soaps contain the stearic acid residue. B is ρ i el 1

The content of free fatty acids in these metal 50
soap is preferably low and is preferred

less than 2 percent by weight. A mixture of 74.7 g of paraffinic mineral oil

In connection with the weight percentage having a viscosity of 60 Centistok at 37.8 ⁰ C the mixture of the metal soaps is in the following and an aniline point of 111.7 ° C, 8 g Bariumhinzuweisen: The barium soap increases when using 55 stearate (melting point 235 ° C ), 5 g lithium stearate in an amount of more than 65 weight percent den (melting point 221 ⁰ C), 2 g aluminum stearate (melt electrical contact resistance and deteriorated point 112 ⁰ C), polychlorotriphenyl lies, 0.1 g 4,4'-Tebat an amount of less than 40 percent by weight of tramethyldiaminodiphynylmetiian and 0.2 g of sorbitol. The resistance of the electrical conact to monooleate is stirred and to 230 to 24 ° C over welding; the lithium soap increased at 60 heated.

Use an amount less than 25 Ge. After homogenization, the mixture is in

weight percent the electrical contact resistance poured a shell, cooled to room temperature

and deteriorates at an amount before, more than, and on a die-roll mill; then

The foam remaining in the fat is less than 40 percent by weight Welding; the aluminum soap yields at a 65 vacuum removed. The fat obtained

An amount of more than 20 percent by weight is stable and has a penetration according to

tact fat with a low pour point and poor ASTM of 332 as well as a pour point of 120 ^J C.

Heat resistance, and an aluminum soap in the fat is on one made of copper and brass

existing contact applied. The behavior of the fat is shown as Example 1 in the table.

Example 2

A mixture of 70.5 g paraffinic mineral oil with a viscosity of about 50 centistok at 37.8 ° C and an aniline point of 102.7 ° C, 10 g barium stearate (melting point 235 ° C), 7 g lithium stearate, 4 g aluminum stearate, 8 g ^Polychlorti: phenyl, and 0.5 g of 2,6-di-tert-butylphenol is heated to 235-245 ⁰ C. After homogenization, the mixture is cooled, ground and treated in a manner similar to that in Example 1. The test results obtained in a manner similar to Example 1 are shown in the table.

Example 3

A mixture of 73.8 g of paraffinic mineral oil having a viscosity of 120 Centistok at 37.8 ° C and an aniline point of 114.9 ⁰ C, 6 g of barium stearate (melting point 250 ° C), 4 g Lithiumslearat (melting point 221 ° C) , 2 g of aluminum stearate, 14 g of polychlorotriphenyl and 0.2 g of the sodium salt of dinonylnaphthalene sulfonate are stirred and heated to about 250.degree. The clear, liquid solution is treated as in Example 1. The test results obtained in a manner similar to Example 1 are shown in the table.

Example 4

A mixture of 75.4 g paraffinic mineral oil with a viscosity of 80 centistok at 37.8 ° C and an aniline point of 114.0 ° C, 7 g barium stearate, 5 g lithium laurate (melting point 219 ° C), 1.5 g aluminum stearate , 8 g Hexachlordiphenyl, 0.1 g and 3 g Tetrabace SorbiUnmonooleat is heated in a beaker reaches about 24O ⁰ C until its temperature. The mixture obtained is treated further as in Example 1. The test results obtained as in Example 1 are given in the table.

B e i s ρ i e i 5

A mixture of 72.9 g of paraffinic mineral oil with a viscosity of 60 centistok at 37.8 ° C. and an aniline point of 111.7 ° C., 10 g of barium stearate, 5 g of lithium laurate (melting point V. 9 ° C.), 3 g of aluminum stearate and 9.1 g of tetrachlorodiphenyl is stirred and heated in a beaker until its temperature has reached about 250 ° C. The mixture obtained is treated in a manner similar to that in Example 1. The results of the tests carried out as in Example 1 are given in the table.

Example 6

l ^; In a mixture of 70.9 g of paraffinic mineral oil with a viscosity of 80 centistok at 37.8 ° C and an aniline point of 114.0 ° C, 9 g of barium stearate (melting point 240 ° C), 6 g of lithium laurate (melting point 219 ° C.), 2 g of aluminum steardt (melting point 110 ° C.), 12 g of polychlorotriphenyl and 0.1 g of tetrabase are stirred, heated in a beaker and then treated in a manner similar to that in Example 1. The test results obtained as in Example 1 are given in the table.

Example 7

A Ger.v ch made from 69.8 g of paraffinic mineral oil with a viscosity of 78.2 centistok at 37.8 ° C. and an aniline point of 104.2 ° C., 10 g of barium stearate. 6 g lithium stearate, 2 g aluminum stearate, 11 g polychlorotriphenyl, 0.2 g tetrabase and 1 g

"Span 80" is stirred, heated in a beaker and then treated as in Example 1. the Experimental results as obtained in Example 1 are shown in the table.

Example 8

A mixture of 73.7 g of paraffinic mineral oil with a viscosity of 80 Centistok at 37.8 "" ¹ C and an aniline point of 114.0 ° C, 8 g of barium stearate, 6 g of lithium stearate, 2.2 g of aluminum stearate, 10 g of polychlorotriphenyl and 0.1 g of tetrabase is stirred, heated in a beaker and treated in a manner similar to that in Example 1. The test results obtained as in Example 1 are given in the table.

Example 9

A mixture of 76.5 g parafrinischera mineral oil having a viscosity of 120 Centistok at 37.8 ⁰ C and an aniline point of 114.9 ° C, 8 g of barium stearate, lithium stearate 4 g, 1.5 g of aluminum stearate and 9 g Hexachlordiphenyl 1 0 g of 2,2'-methylenebis (4-methyl-6-teit.-butylphenol) is stirred, heated in a beaker and treated in a manner similar to that in Example 1. The test results obtained in a manner similar to Example 1 are shown in the table.

Example 10

A mixture of 73.8 g of paraffinic mineral oil with a viscosity of 60 centistok at 37.8 ° C and an aniline point of 117.2 ° C, 7 g barium stearate, 6 g lithium stearate, 2 g aluminum stearate, 11 g of polychlorotriphenyl and 0.2 g of tetrabase are stirred, heated in a beaker and similar Way treated as in Example 1. As in the example The test results obtained are shown in the table.

The tetrabase mentioned in the preceding examples is 4,4'-tetramethyldiaminodiphenylmethane.

table

Combination of

Contact metals

Contact pressure (g)

Opening speed

(cm · see " ¹ )

Opening force (g)

Contact voltage (V) ..

Contact current (A)

Contact resistance (mü)

0

10,000

30,000

50,000

Number of switches on and off before welding

Copper brass

200

30th

100

Alternating current

100

Peak load:

30 normal:

18 39 28

> 50

j Kupfei {brass t

200

30th

100

Alternating current

100

Peak load:

30 normal:

24 55 79

Copper brass

Alternating current

Lamp load copper
Phosphor bronze
200

30th
100

Alternating current

100

Lamp load

normal: 4 | normal: 4
Number of operations

4th
25th
32
44

Copper nickel silver 200

30th

100

Alternating current

100

Peak load:

30 normal:

29

85

162

> 50000 I> 50000 j> 50000
Table (continued)

Copper brass

300

20th

100

Alternating current

100

Peak load:

30 normal:

10 42 78

35000> 50000

Combination of contact metals

Contact pressure (g)

Opening speed

(cm · see " ¹ )

Opening force (g)

Contact voltage (V). -

Contact current (A)

copper

Kupier ι «vuh '« ·''. ■

Beryllium- I Beryllium- brass

Copper 300

20th

100

Alternating current

100

Lamp load

Copper 300

20 100

Alternating current

100

Lamp load

normal: 4 normal:

Alternating current

Peak load:

30th
normal: 4

copper
Beryllium copper
200

30th
100

Alternating current

100

Pointed. load:

30th
j normal: 4

Number of operations

Contact resistance (mil) 0

10,000

30,000

50,000

Number of operations

until welding. -

4 18 15 22

29 48 75

22nd
39
69

15th
48
83

50000 ^; > 50,000,000 i> 50,000

Copper brass

200

30 100

Alternating current

100

Peak load:

30 normal:

255 1250 2

3

Copper brass

200

100

Alternating current

Peak load:

30 normal:

325 1580 1420

Claims (5)

Patent claims: 1. Electrical contact grease, consisting of 1. a major amount of paraffinic mineral oil; 2. 10 to 20 percent by weight of a mixture of metallic soaps as a thickener, wherein the mixture of metal soaps is essentially made up a) 40 to 65 percent by weight barium soap, b) 25 to 40 percent by weight lithium soap and c) 10 to 20 weight percent aluminum soap composed 3. 7 to 15 percent by weight of at least one table hydrocarbons,
4. 0.01 to 3.0 weight percent antioxidant and optionally characterized in that it contains barium soap, Liihiumseife and aluminum soap according to the formulas Ba (RCOO) ₂ , Li (RCOO) and Al (RCOO) ₃ , where R is an alkyl radical having 1 "to 20 carbon atoms. 3. Electrical contact grease according to claim 1, characterized in that it is a chlorinated aromatic hydrocarbon or a derivative of a chlorinated aromatic hydrocarbon trichlorodiphenyl, tetrachlorodiphenyl, pentachlorodiphenyl, hexachlorodiphenyl, polychlorotriphenyl, pentachlorodiphenyl oxide. Pentachlorophenyl benzoate, hexachlorodiphenyl methane and
may contain nylketone. 4. Electrical contact grease according to claim 1, the following description emerges. characterized in that it consists of as antioxy A contact grease according to the invention dation agent 0.01 to 3.0 percent by weight η-butyl, a main amount of paraffinic mineral oil, 10 ρ - aminophenol, Di - see. - butyl - ρ - phenylene - 45 to 20 percent by weight of a mixture of metal diamine, 4,4'-Tetramethyldiaminodiphenymethane, soap as a thickener and 7 to 15 weight-λ - Naphthylamine, n, n '- disalicylidene - 1.2 - percent of at least one chlorinated aromatic pylenediamine, 2,6 - di - tert. - butyl - phenol, 2,4-dihydrocarbon or a derivative thereof. The methyl - 6 - tert. According to the invention, there is a - butylphenol, 2,6 - di-tert-butyl mixture of the metal soaps ρ - cresol, 4,4 '- methylene - bis - (2.6 - di - tert.- 50 from 40 to 65 percent by weight of barium soap, 25 to butylphenol), 2,2 '- methylene - bis - (4 - methyl - 40 percent by weight lithium soap and 10 to 20 θεό - tert - butylphenol), 4,4' - butylidene bis (2 percent by weight aluminum soap novel '; Conthyl-6-tert.-butylphenol) may contain. clock bold according to the invention prevents the failure 5. Electrical contact grease according to claim 1, an electrical contact and its combination thereby characterized in that it adheres as an anti-rust agent 55 by welding and ensures equal to -0.01 up to 4.0 percent by weight sorbitan monooleate, provides a satisfactory contact effect during a salt of Dinonylnaphthalinsulfonate or a longer period, especially when using * - (2-Carboxyphenoxy) stearic acid. application to electrical contacts made of corrodible Metals such as copper, brass, phosphorus bronze, beryllium — copper, or nickel — silver are. Preferably become the fat mass Anti-rust and / or anti-oxidants added. For a contact grease according to the invention, a chlorinated aromatic hydrocarbon or The present invention relates to an electrical a derivative of such a boiling point of contact grease, which are used in particular for power switches of more than 300 ⁰ C. Chlorinated aroelectric machines and devices is suitable. matic hydrocarbons or derivatives thereof