CN102952604A - Composite zirconium-based urea bipolymer grease and preparation method thereof - Google Patents

Abstract

The invention provides composite zirconium-based urea bipolymer grease and a preparation method thereof. The composite zirconium-based urea bipolymer grease comprises: by weight, 1) 1 to 59% of composite zirconium which is produced by a reaction of at least one higher fatty acid, at least one aromatic acid, and an oxide and/or a hydroxide of zirconium, wherein a mole ratio of the at least one aromatic acid to the at least one higher fatty acid is (0.5 to 7): 1, 2) 1 to 59% of a urea bipolymer, and 3) 40 to 95% of lubrication base oil. The composite zirconium-based urea bipolymer grease contains the composite zirconium as a densifier and the urea bipolymer. The composite zirconium-based urea bipolymer grease has excellent extreme pressure wear resistance, a long lubrication life, good water resistance, colloid stability, a high dropping point and good heat stability.

Description

A kind of compound zirconium base two polyurea greases and preparation method thereof

Technical field

The present invention relates to lubricant, definite a kind of compound zirconium base two polyurea greases and preparation method thereof that say.

Background technology

Zirconium belongs to IVB family as a kind of transition metal, is positioned at for the 5th cycle.Zirconium-containing compound has good lubrication, is often used as slip additive, such as CN 101113382 and JP1973038444 the oxide compound of zirconium has been improved abradability as lubricant additive; WO2007143414 and US 20060063682 have introduced zirconium tetrafluoride and can be used as wear reducing additive and become one of component of lubricant; US 20060254823 finds that the lubricant that contains the 2 ethyl hexanoic acid zirconates shows good anti-heavy loading and abrasion resistance; US 20050043189 finds that fluozirconate such as fluorine zirconic acid aluminium can be used as oxidation retarder and is used in the lubricant; DE 102004021812 finds that the inorganic salt such as zirconium carbonate, sulfonic acid zirconium or zirconium phosphate are joined the lubricating grease the inside can improve abrasion resistance.

As the patent that viscosifying agent prepares the zirconium base grease US 4189387 is arranged with zirconates, viscosifying agent is a kind of zirconates, the Hypophosporous Acid, 50 that is replaced by alkyl or monocarboxylic acid react with zirconium hydroxide and make, prepared fat has preferably extreme pressure property, but dropping point is not high, and the effect relatively preferably viscosifying agent of product contains fluorine element, and raw material is difficult for obtaining.Existing dimerization urea-base grease patent is numerous, but itself extreme pressure property and mechanical stability Shortcomings need to add additive and improves, but the susceptibility of additive is not good enough.

Summary of the invention

The invention provides a kind of compound zirconium base two polyurea greases, this lubricating grease contains compound zirconium viscosifying agent and two polyurea compounds simultaneously.

The present invention also provides above-mentioned preparation of greases method.

Compound zirconium base two polyurea greases provided by the invention take lubricating grease weight as benchmark, comprise following component:

1) compound zirconium 1%-59%, preferred 3%-40%, most preferably 5%-30%;

2) two polyureas 1%-59%, preferred 2%-40%, most preferably 2%-30%;

3) lubricating base oil 40%-95%, preferred 50%-93%, most preferably 60%-90%.

Described compound zirconium is the compound zirconium soap that is formed by the oxide compound of higher fatty acid and aromatic acid and zirconium and/or oxyhydroxide reaction, comprises higher fatty acid oxygen zirconium and aromatic acid oxygen zirconium.The mol ratio of aromatic acid and higher fatty acid is 0.5～7: 1, preferred 1～4: 1.

The oxide compound of described zirconium and/or oxyhydroxide can be ZrO ₂, ZrO (OH) ₂, ZrO ₂XH ₂O, ZrO (OH) ₂XH ₂O or its mixture, preferred ZrO (OH) ₂

Described higher fatty acid is that carbon number is 8-24, straight chain fatty acid or the hydroxy fatty acid of preferred 10-20, in preferred lauric acid, oleic acid, palmitinic acid, stearic acid, 12-oxystearic acid, the eicosyl carboxylic acid etc. one or more, particularly preferably 12-oxystearic acid.

Described aromatic acid is the carboxylic acid that has at least 1 carboxyl and aromatic ring directly to link to each other, and other substituting group can be the alkyl or aryl of hydrogen, alkyl, thiazolinyl, alkynyl, aryl, fluoro or perfluoro etc.The preferred binary aromatic acid of described aromatic acid, for example, can be selected from the phthalic acid, m-phthalic acid, terephthalic acid of phthalic acid, m-phthalic acid, terephthalic acid, replacement etc., one or more in the biphenyl dicarboxylic acid of preferred phthalic acid, m-phthalic acid, terephthalic acid, biphenyl dicarboxylic acid, santowax dioctyl phthalate, replacement, the santowax dioctyl phthalate etc.

Said two polyureas have following structure:

R wherein ¹That aryl or carbon number are 8～24 alkyl or cycloalkyl, the phenyl that preferred phenyl or C1～C3 alkyl or halogen replace, or carbon number is 10～18 alkyl or cycloalkyl.

R wherein ³Can be that carbon number is 6～30, preferred 6～20 arylidene, alkylidene group or cycloalkylidene, at least a in preferred tolyl, methyldiphenyl base, dicyclohexyl methyl, an xylylene and the hexylidene.

Described lubricant base can be mineral oil, synthetic oil, vegetables oil or their mixture, and 100 ℃ of kinematic viscosities are 2mm ²/ s-150mm ²/ s, preferred 4mm ²/ s-60mm ²/ s.Synthetic oil can be poly-a-olefin oil (PAO), ester class oil, alkyl-silicone oil, Fischer-Tropsch synthesis oil etc.

Can also contain various additives in the lubricating grease of the present invention, such as oxidation inhibitor, anti-wear agent, rust-preventive agent etc.The preferred arylamine kind antioxidant of oxidation inhibitor wherein accounts for the 0.1%-5% of lubricating grease gross weight, and preferred 0.2%-1% can be pentanoic, phenyl-a-naphthylamine, di-iso-octyldiphenylamine or their mixture, preferred di-iso-octyldiphenylamine.

The preparation method of described compound zirconium base two polyurea greases comprises:

(1) in reactor A, the oxide compound of higher fatty acid and aromatic acid and zirconium and/or oxyhydroxide in the part base oil (account for whole base oil weight 30%～60%) are mixed thermal dehydration;

(2) add the vulcabond that is dissolved in the part base oil in the product of reactor A or in reactor B, add monoamine again and react, wherein the mol ratio of vulcabond and monoamine is 1: 2;

(3) mixing of materials among the reactor A is even, or mix after the material merging with reactor A and B, be warmed up to 200 ℃ of-220 ℃ of constant temperature refinings, add the cooling of surplus base oil, add the additive of necessity, obtain finished product.

Specifically, preparation method of the present invention can finish in a reactor, also can use two reactors.

In the step (1), base oil is mixed first with higher fatty acid and/or aromatic acid, base oil is mixed with oxide compound and/or the oxyhydroxide of zirconium first; Higher fatty acid and aromatic acid can dewater with oxide compound and/or the oxyhydroxide reaction of zirconium in base oil simultaneously, also can react respectively dehydration.Preferably higher fatty acid and base oil are heated to 50 ℃-80 ℃, the oxide compound and/or the oxyhydroxide that add required zirconium react, 80 ℃-90 ℃ constant temperature 60-90 minute, rear intensification dehydration, add aromatic acid at 105 ℃-150 ℃, constant temperature stirred 5-60 minute, dehydration.

The H of higher fatty acid and aromatic acid in theory ⁺During total amount of substance sum equals all and the amount of substance of zirconium white and/or zirconium hydroxide, but the amount of substance of zirconium white and/or zirconium hydroxide can excessive 1～10%.

In the step (2), add the vulcabond that is dissolved in the part base oil in the product of reactor A or among the reactor B, stir, 90 ℃-120 ℃ add monoamine, react 2-8 minute, and the mol ratio of vulcabond and monoamine is 1: 2.

Said vulcabond structure is OCN-R ³-NCO, R ³Can be that carbon number is 6～30, preferred 6～20 arylidene, alkylidene group or cycloalkylidene, preferred tolyl, methyldiphenyl base, dicyclohexyl methyl, an xylylene, hexylidene etc.For example described vulcabond can be tolylene diisocyanate (TDI), methyldiphenyl group diisocyanate (MDI), 1,6-hexylidene diisocyanate (HDI), dicyclohexyl methyl vulcabond (HMDI), or at least a in the xylylene vulcabond (XDI) etc.

Said monoamine can be aliphatic amide, aliphatic cyclic amine or arylamine, and structural formula is R ¹-NH ₂, R wherein ¹That aryl or carbon number are 8～24 alkyl or cycloalkyl, the phenyl that preferred phenyl or C1～C3 alkyl or halogen replace, or carbon number is 10～18 alkyl, cycloalkyl.Preferred monoamine can be the arylamine that is selected from aniline, m-chloro aniline, p-Chlorobenzoic acid amide, para-totuidine, and/or is selected from the aliphatic amide of amino dodecane, tetradecy lamine, cetylamine, stearylamine.

In the step (3), the mixing of materials among the reactor A is even, or mix after the material of reactor A and B merged, be warmed up at last 200 ℃-220 ℃ constant temperature 5-10 minute; Add the surplus lubricating base oil at 160 ℃-220 ℃, treat that temperature is cooled to 100 ℃-120 ℃, add necessary additive, stir circulating filtration, homogenizing, the degassed finished product that obtains.

Lubricating grease of the present invention compared with prior art has fabulous extreme pressure anti-wear and long lubricating life, simultaneously, also has the performances such as good water resisting property, colloid stability, high dropping point, heat-resistant quality.This product preparation process is simple, constant product quality.

Embodiment

Embodiment 1

Feed composition: ZrO (OH) ₂(3.4kg); 12-oxystearic acid (4.8kg); Phthalic acid (2.6kg); Stearylamine (1.5kg); MDI (0.7kg); 500SN (40kg); To p-di-iso-octyldiphenylamine (0.1kg).

A volume be 110L and with heating, stir, add the 4.8kg12-oxystearic acid in the normal-pressure reaction kettle of circulation, cooling and 100 ℃ of kinematic viscosity of 15kg are 11mm ²The HVI500SN lubricating base oil of/s stirs, and heats to 80 ℃, constant temperature 10 minutes; Add 3.4kg ZrO (OH) ₂, temperature is controlled at about 90 ℃, stirs 60 minutes; Be warmed up to 110 ℃ under stirring, added 2.6kg O-phthalic acid-respons 30 minutes;

Another volume be 5L and with heating, stir, add the 5kg500SN base oil in the normal-pressure reaction kettle of circulation, cooling, be preheating to 90 ℃ and added the 0.7kgMDI rapid stirring 4 minutes, adding the 1.5kg stearylamine under the rapid stirring stirred 4 minutes, the mol ratio of added MDI and stearylamine is 1: 2,120 ℃ of constant temperature 20 minutes obtains two polyureas.

Gained two polyureas are all squeezed in the upper still, stirred, be warmed up at last 200 ℃, constant temperature added the 500SN lubricating base oil of 20kg after 5 minutes, cooled; Treat that temperature is cooled to 110 ℃, after adding 0.1kg stirs 10 minutes to p-di-iso-octyldiphenylamine, circulating filtration, homogenizing, the degassed finished product that obtains.Assay sees Table 1.

In the lubricating grease that the present embodiment obtains, take lubricating grease weight as benchmark, consist of: two polyureas 4.2%; Lubricating base oil 76.5%; 12-oxystearic acid oxygen zirconium 10.8%; Phthalic acid oxygen zirconium 8.3%; To p-di-iso-octyldiphenylamine 0.2%.The mol ratio of phthalic acid and 12-oxystearic acid is 1: 1.

The two polyureas molecular structural formulas that contain in the component are:

Embodiment 2

Feed composition: ZrO (OH) ₂(3.4kg); Stearic acid (4.55kg); Terephthalic acid (2.66kg); Stearylamine (1.5kg); MDI (0.7kg); PAO 10 (110kg); N-phenyl-a-naphthylamine (0.12kg).

A volume be 150L and with heating, to stir, add 4.55kg stearic acid, 2.66kg terephthalic acid and 40kg100 ℃ of kinematic viscosity in the normal-pressure reaction kettle of circulation, cooling be 10mm ²PAO 10 lubricating base oils of/s stir, and heat to 80 ℃, constant temperature 10 minutes; Add 3.4kgZrO (OH) ₂, temperature is controlled at about 90 ℃, stirs 90 minutes, heats up and catches up with water; After having caught up with water, added the 0.7kgMDI rapid stirring 4 minutes, add the 1.5kg stearylamine under the rapid stirring and stirred 4 minutes, the mol ratio of added MDI and stearylamine is 1: 2,120 ℃ of constant temperature 20 minutes is warmed up to 200 ℃ of constant temperature 5 minutes at last.Then, be cooled to 160 ℃, add PAO 10 lubricating base oils of 70kg; Treat that temperature is cooled to 110 ℃, adding accounts for lubricating grease weight 0.12kg N-phenyl-a-naphthylamine and stirs after 10 minutes, circulating filtration, homogenizing, the degassed finished product that obtains.Assay sees Table 1.

In the lubricating grease that the present embodiment obtains, take lubricating grease weight as benchmark, consist of: two polyureas 1.8%; Lubricating base oil 90.1%; Zirconyl stearate 4.4%; Terephthalic acid oxygen zirconium 3.6%; N-phenyl-a-naphthylamine 0.1%.Terephthalic acid and stearic mol ratio are 1: 1.

Embodiment 3

Feed composition: ZrO ₂(6kg); 12-oxystearic acid (4.8kg); M-phthalic acid (8kg); Amino dodecane (1.31kg); MDI (0.89kg); PAO 6 (50kg); To p-di-iso-octyldiphenylamine (0.2kg).

Method by example 1 prepares compound zirconium base two polyurea greases, and different is that the monoamine that uses is amino dodecane, ZrO ₂, 12-oxystearic acid and m-phthalic acid consumption also change, each performance data of lubricating grease finished product that obtains sees Table 1.

In the lubricating grease that the present embodiment obtains, take lubricating grease weight as benchmark, consist of: two polyureas 3.1%; Lubricating base oil 70.4%; 12-oxystearic acid oxygen zirconium 7.9%; Terephthalic acid oxygen zirconium 18.3%; To p-di-iso-octyldiphenylamine 0.3%.The mol ratio of m-phthalic acid and 12-oxystearic acid is 3: 1.

Embodiment 4

Feed composition: ZrO (OH) ₂(0.5kg); 12-oxystearic acid (0.3kg); 4,4 '-biphenyl dicarboxylic acid (0.7kg); Para-totuidine (1.17kg); Stearylamine (2.93kg); TDI (1.90kg); 150BS (16kg).

Method by example 1 prepares compound zirconium base two polyurea greases, and each raw material all changes, and each performance data of lubricating grease finished product that obtains sees Table 1.

In the lubricating grease that the present embodiment obtains, take lubricating grease weight as benchmark, consist of: two polyureas 25.7%; Lubricating base oil 68.4%; 12-oxystearic acid oxygen zirconium 1.5%; 4,4 '-biphenyl dicarboxylic acid oxygen zirconium 4.4%.4,4 '-mol ratio of biphenyl dicarboxylic acid and 12-oxystearic acid is 3: 1.

Comparative Examples 1

With 280g 500SN oil (100 ℃ of viscosity 11mm ²/ s), 90g 12-oxystearic acid adds in the normal oleosterin still, stirs, become the homogeneous system after being warmed up to 90 ℃, add 24gZrO (OH) this moment ₂, be warming up to 105 ℃ of draining saponification 2 hours, after be warming up to 205 ℃, add 180g quenching oil 500SN, stir cooling, and normal temperature grinds, obtain the zirconium base grease.Grease composition: base oil 81%, viscosifying agent 19%.Each physicochemical property of gained fat sees following table for details.

Comparative Examples 2

With 280g 500SN oil (100 ℃ of viscosity 11mm ²/ s), 45g 12-oxystearic acid and 15g sebacic acid add in the normal oleosterin still, stirs, becoming the homogeneous system after being warmed up to 90 ℃, be dissolved with 12.3g LiOHH with 50g this moment ₂The aqueous solution of O slowly adds wherein, is warming up to 105 ℃ of draining saponification 2 hours, after be warming up to 205 ℃, add 180g quenching oil 500SN, stir cooling, and normal temperature grinds, obtain the zirconium base grease.Grease composition: base oil 88%, viscosifying agent 12%, wherein diprotic acid and monoprotic acid mol ratio are 0.5: 1.Each physicochemical property of gained fat sees following table for details.

Each lubricating grease properties of sample data of table 1

Claims (16)

1. compound zirconium base two polyurea greases take lubricating grease weight as benchmark, comprise following component:

1) compound zirconium 1%-59%, described compound zirconium is formed by oxide compound and/or the oxyhydroxide reaction of higher fatty acid and aromatic acid and zirconium; 2) two polyureas 1%-59%; 3) lubricating base oil 40%-95%.

2. according to lubricating grease claimed in claim 1, take lubricating grease weight as benchmark, comprise following component:

1) compound zirconium 3%-40%, described compound zirconium is formed by oxide compound and/or the oxyhydroxide reaction of higher fatty acid and aromatic acid and zirconium; 2) two polyureas 2%-40%; 3) lubricating base oil 50%-93%.

3. according to lubricating grease claimed in claim 1, described higher fatty acid is that carbon number is straight chain fatty acid or the hydroxy fatty acid of 8-24.

4. according to lubricating grease claimed in claim 1, described higher fatty acid is selected from one or more in lauric acid, oleic acid, palmitinic acid, stearic acid, 12-oxystearic acid, the eicosyl carboxylic acid.

5. according to lubricating grease claimed in claim 1, described aromatic acid is the binary aromatic acid.

6. according to lubricating grease claimed in claim 1, described aromatic acid is selected from the phthalic acid, m-phthalic acid, terephthalic acid, biphenyl dicarboxylic acid, santowax dioctyl phthalate, the biphenyl dicarboxylic acid of replacement, one or more in the santowax dioctyl phthalate of phthalic acid, m-phthalic acid, terephthalic acid, replacement.

7. according to lubricating grease claimed in claim 1, the mol ratio of aromatic acid and higher fatty acid is 0.5～7: 1.

8. according to lubricating grease claimed in claim 1, described two polyureas have following structure:

R wherein ¹Be selected from aryl or carbon number and be 8～24 alkyl or cycloalkyl, R wherein ³That carbon number is 6～30 arylidene, alkylidene group or cycloalkylidene.

9. according to lubricating grease claimed in claim 8, R wherein ¹Be selected from the phenyl that phenyl or C1～C3 alkyl or halogen replace, or carbon number is 10～18 alkyl, cycloalkyl, R wherein ³Be selected from least a in tolyl, methyldiphenyl base, dicyclohexyl methyl, an xylylene and the hexylidene.

10. according to lubricating grease claimed in claim 1, described lubricant base is mineral oil, synthetic oil, vegetables oil or their mixture, and 100 ℃ of kinematic viscosities are 2mm ²/ s-150mm ²/ s.

11. the preparation method of described compound zirconium base two polyurea greases of one of claim 1-10 comprises:

(1) in reactor A, higher fatty acid and aromatic acid are mixed thermal dehydration with oxide compound and/or the oxyhydroxide of zirconium in the part base oil;

(2) add the vulcabond that is dissolved in the part base oil in the product of reactor A or in reactor B, add monoamine again and react, wherein the mol ratio of vulcabond and monoamine is 1: 2;

(3) mixing of materials among the reactor A is even, or mix after the material merging with reactor A and B, be warmed up to 200 ℃ of-220 ℃ of constant temperature refinings, add the cooling of surplus base oil, add the additive of necessity, obtain finished product.

12. according to the described preparation method of claim 11, said vulcabond structure is OCN-R ³-NCO, R ³That carbon number is 6～30 arylidene, alkylidene group or cycloalkylidene.

13. according to the described preparation method of claim 11, said vulcabond is selected from tolylene diisocyanate, the methyldiphenyl group diisocyanate, 1, the 6-hexylidene diisocyanate, dicyclohexyl methyl vulcabond, or at least a in the xylylene vulcabond.

14. according to the described preparation method of claim 11, said monoamine structural formula is R ¹-NH ₂, R wherein ¹That aryl or carbon number are 8～24 alkyl or cycloalkyl.

15. according to the described preparation method of claim 11, said monoamine is selected from the phenyl that phenyl or C1～C3 alkyl or halogen replace, or carbon number is 10～18 alkyl, cycloalkyl.

16. according to the described preparation method of claim 11, said monoamine is the arylamine that is selected from aniline, m-chloro aniline, p-Chlorobenzoic acid amide, para-totuidine, and/or is selected from the aliphatic amide of amino dodecane, tetradecy lamine, cetylamine, stearylamine.