CN1539934A - Current variable fluid material of modified Nano composite granules between kaoline and oxide of titanium, and prepration method - Google Patents
Current variable fluid material of modified Nano composite granules between kaoline and oxide of titanium, and prepration method Download PDFInfo
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- CN1539934A CN1539934A CNA031146694A CN03114669A CN1539934A CN 1539934 A CN1539934 A CN 1539934A CN A031146694 A CNA031146694 A CN A031146694A CN 03114669 A CN03114669 A CN 03114669A CN 1539934 A CN1539934 A CN 1539934A
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Abstract
An electric rheopectic liquid of composite modified kaolinite/Ti oxide nanoparticles is prepared from the methyl silica oil and the dispersed phase prepared from the modified kaolinite and Ti oxide by sol-gel method, which includes such steps as reaction of kaolinite on dimethyl sulfoxide to generate intercalated compound, using sodium chloride for intercalating substitute to obtain intercalated kaolinite/sodium chloride compound and wrapping it by Ti oxide by sol-gel method. Its advantages are high rheopectic effect settling stability and wide working temp range.
Description
Technical field the present invention relates to a kind of electro-rheologic fluid material and preparation method thereof, particularly a kind of modified kaolin/titanium oxide Nano composite granules electro-rheologic fluid material and preparation method thereof.
The background technology electrorheological fluid is a kind of SMART FLUID, and it normally is scattered in the transformer oil of low-k and the suspension system that forms by the solid particulate of high-k, low conductivity.This system can realize liquid-solid transformation in moment under effect of electric field, and this transformation behavior has advantages such as quick, reversible, adjustable, so there is important use to be worth on automatization, vibroshock, clutch coupling, deoscillator, stepless speed-regulating device and optics and printing equipment.At present, the performance of electrorheological fluid does not also reach the practicability requirement, and wherein topmost restraining factors are: the mechanics value is not high, resistance to settling is poor, temperature effective is low, cost is high.Mineral-type materials once was the main research object of electrorheological fluid, and European patent EP 0396237 is utilized the dispersion particle of silico-aluminate as electrorheological fluid, and its composition is (Al
2O
3)
b(SiO
2)
c, b: c in 1: 1~1: 9 scope, this material composition good stability, corrosion-resistant, temperature effective is good, but exists mechanical property on the low side, sedimentation resistance stability is poor, to shortcomings such as equipment attrition are big; Many afterwards employing organic polymer materials are the disperse phase (as H.Block U.K.Patent, 2170510) of electrorheological fluid, although its mechanics value is better than inorganic materials height and resistance to settling usually, but complicated process of preparation, the cost height, the toxicity that has is big, is difficult to realize industrialization.Whether rely on water to make activator according to electro-rheologic fluid material, electro-rheologic fluid material can be divided into moisture er material and anhydrous electric rheological liquid material again.Early stage research work mainly concentrates on the moisture er material, and as starch, gelatin etc., yet this kind material only just has electric rheological effect under the condition that has water to exist.Owing to be subjected to the influence of water, with the electrorheological fluid unstable properties of this material preparation, temperature influence is big; The leakage current density that the added electric field after-current becomes liquid increases, and energy consumption raises; And the existence of water has also reduced the electrorheological fluid breakdown characteristics; Simultaneously, the salt ion in the dissolved electro-rheologic fluid material can cause corrosion etc. to device in water.Investigators have successfully developed the anhydrous electric rheological liquid material again subsequently, as semi-conductor superpolymer electro-rheologic fluid material, the inorganic er material of inorganic oxide electro-rheologic fluid material and doped with rare-earth elements etc., these materials have overcome the part shortcoming of moisture er material, advantage is the operation temperature area with broad, leakage current density is little, and energy consumption is little.But exist also that the mechanics value is not high, resistance to settling is poor, problem such as complicated process of preparation or cost height, this has still hindered the widespread use of electrorheological fluid.
Summary of the invention the object of the invention provides a kind of novel modified kaolin and the interactional electro-rheologic fluid material of titanium oxide, and its disperse phase is modified kaolin/titanium oxide cladding nanometer matrix material.These preparation method's characteristics are to adopt sol-gel method and graft process to combine, and at first prepare kaolin/sodium-chlor intercalated compound; Utilizing sol-gel method then is nuclear with kaolin/sodium-chlor intercalated compound, and titanium oxide is wrapped in its surface, forms the cladding nanometer matrix material.Both had higher mechanics value, wide operation temperature area and resistance to settling preferably by the electrorheological fluid of this material and methyl-silicone oil preparation, reduced the cost of electrorheological fluid again, and preparation technology is simple, nontoxic, reaction process is easy to control, and equipment is not had particular requirement.Having given full play to the speciality of inorganic/inorganic nano composite material, produced preferable synergistic effect, is a kind of er material of high comprehensive performance.
Description of drawings
The relation of Fig. 1 modified kaolin/titanium oxide, titanium oxide, kaolin electrorheological fluid shear-stress and strength of electric field
Fig. 2 modified kaolin/titanium oxide composite material by electric current becomes liquid in the relation of same electric field down cut stress and shearing rate not
Modified kaolin/its shear-stress of titanium oxide composite particles electrorheological fluid of the different intercalation method preparations of Fig. 3
And the relation between the strength of electric field
Embodiment is raw materials used chemical pure kaolin, chemical pure sodium-chlor, chemical pure tetrabutyl titanate, analytical pure dehydrated alcohol etc.Select for use dimethyl sulfoxide (DMSO) to make presoma, at first prepare the kaolin intercalated compound; Then an amount of this intercalated compound is joined in the saturated solution of sodium-chlor, fully stirs, grind after boiling dry out solvent, pale powder.On the tabletting machine this powder is being depressed to thin slice about 5mm in 12MPa.Thin slice is through 100 ℃ of half an hour, 200 ℃ of half an hour, 300 ℃ of calcinings of 2 hours.The calcining sample is through grinding, and deionized water repeatedly washs, in filtrate not till the chloride ion-containing.Obtain kaolin/sodium-chlor intercalated compound after sample drying, the grinding.Again a certain amount of kaolin/sodium-chlor intercalated compound is joined in a certain amount of dehydrated alcohol, at room temperature fully stir; Then a certain amount of tetrabutyl titanate and a certain amount of dehydrated alcohol are mixed, and under stirring condition, it is splashed in the alcohol suspension of kaolin/sodium-chlor intercalated compound, further fully stir; Splash into a certain amount of dehydrated alcohol that contains a small amount of secondary deionized water at last, stirring at room 5 hours; Again this system is left standstill and to obtain opaque gel a night; With this gel 80 ℃ dry 4 hours down, again 90 ℃ of dryings two hours, get final product loosely the pale solid powder through grinding; This sample and silicone oil are mixed with electrorheological fluid according to a certain percentage.
The performance of implementation procedure of the present invention and material is by embodiment and description of drawings:
Embodiment one:
Select for use dimethyl sulfoxide (DMSO) to make presoma, 10g kaolin adds the 20ml dimethyl sulfoxide (DMSO) and reacted 8 hours down for 80 ℃, then one week of drying at room temperature, promptly gets the kaolin intercalated compound; An amount of this intercalated compound is joined in the saturated solution of sodium-chlor, and this mixture and weight sodium chloride ratio are 1: 2, fully stir 8 hours, grind after boiling dry out solvent, pale powder.This powder is being depressed to thin slice about 5mm in 12MPa on the tabletting machine.Thin slice is through 100 ℃ of half an hour, 200 ℃ of half an hour, 300 ℃ of calcinings of 2 hours.The calcining sample is through grinding, and deionized water repeatedly washs, in filtrate not till the chloride ion-containing; Sample obtains kaolin/sodium-chlor intercalated compound after drying, the grinding again.At first 3g kaolin/sodium-chlor intercalated compound is joined in the 15ml dehydrated alcohol again, at room temperature fully stir; Then 7ml tetrabutyl titanate and 7ml dehydrated alcohol are mixed, and under stirring condition, it is splashed in the alcohol suspension of kaolin/sodium-chlor intercalated compound, further fully stir; Splash into a certain amount of dehydrated alcohol that contains a small amount of secondary deionized water at last, stirring at room 5 hours; Again this system is left standstill and to obtain opaque gel a night; With this gel 80 ℃ dry 4 hours down, again 90 ℃ of dryings two hours, get final product loosely the pale solid powder through grinding; Is 25% to be mixed with electrorheological fluid with this powdered sample and methyl-silicone oil by particle/silicone oil volume percent.The relation of the shear-stress of electrorheological fluid and strength of electric field, shearing rate is shown in accompanying drawing 1,2.
Embodiment two:
10g kaolin adds the 50ml deionized water and stirring, adds under the 20g sodium-chlor normal temperature to react 8 hours again, boils, and finishes until solvent evaporates.Ground sample, again with this sample 200 ℃ of half an hour, 300 ℃ of half an hour, 550 ℃ 2 hours the calcining.The calcining sample is through grinding, and deionized water repeatedly washs, in filtrate not till the chloride ion-containing; Sample obtains kaolin/sodium-chlor intercalated compound after drying, the grinding again.Again 3g kaolin/sodium-chlor intercalated compound is joined in the 15ml dehydrated alcohol, at room temperature fully stir; Then 7ml tetrabutyl titanate and 7ml dehydrated alcohol are mixed, and under stirring condition, it is splashed in the alcohol suspension of kaolin/sodium-chlor intercalated compound, further fully stir; Splash into a certain amount of dehydrated alcohol that contains a small amount of secondary deionized water at last, stirring at room 5 hours; Again this system is left standstill and to obtain opaque gel a night; With this gel 80 ℃ dry 4 hours down, again 90 ℃ of dryings two hours, get final product loosely the pale solid powder through grinding; Is 25% to be mixed with electrorheological fluid with this powdered sample and methyl-silicone oil by particle/silicone oil volume percent.The shear-stress of electrorheological fluid and strength of electric field relation are as shown in Figure 3.
Embodiment three:
Select for use dimethyl sulfoxide (DMSO) to make presoma, 10g kaolin adds the 20ml dimethyl sulfoxide (DMSO) and reacted 8 hours down for 80 ℃, then one week of drying at room temperature, promptly gets the kaolin intercalated compound; Then an amount of this intercalated compound is joined in the saturated solution of sodium-chlor, mixture and weight sodium chloride ratio are 1: 2, fully stir 8 hours, boil the back and finish until solvent evaporates.Sample was dried by the fire 8 hours down in 150 ℃.Smoke sample through grinding, deionized water repeatedly washs, in filtrate not till the chloride ion-containing; Obtain kaolin/sodium-chlor intercalated compound after sample drying, the grinding.Again 3g kaolin/sodium-chlor intercalated compound is joined in the 15ml dehydrated alcohol, at room temperature fully stir; Then 7ml tetrabutyl titanate and 7ml dehydrated alcohol are mixed, and under stirring condition, it is splashed in the alcohol suspension of kaolin/sodium-chlor intercalated compound, further fully stir; Splash into a certain amount of dehydrated alcohol that contains a small amount of secondary deionized water at last, stirring at room 5 hours; Again this system is left standstill and to obtain opaque gel a night; With this gel 80 ℃ dry 4 hours down, again 90 ℃ of dryings two hours, get final product loosely the pale solid powder through grinding; Is 25% to be mixed with electrorheological fluid with this powdered sample and methyl-silicone oil by particle/silicone oil volume percent.The shear-stress of electrorheological fluid and strength of electric field relation are as shown in Figure 3.
Embodiment four:
Ground in mortar 2 hours under 10g kaolin and the 20g sodium-chlor normal temperature, deionized water repeatedly washs, in filtrate not till the chloride ion-containing; Obtain kaolin/sodium-chlor intercalated compound after sample drying, the grinding.Again 3g kaolin/sodium-chlor intercalated compound is joined in the 15ml dehydrated alcohol, at room temperature fully stir; Then 7ml tetrabutyl titanate and 7ml dehydrated alcohol are mixed, and under stirring condition, it is splashed in the alcohol suspension of kaolin/sodium-chlor intercalated compound, further fully stir; Splash into a certain amount of dehydrated alcohol that contains a small amount of secondary deionized water at last, stirring at room 5 hours; Again this system is left standstill and to obtain opaque gel a night; With this gel 80 ℃ dry 4 hours down, again 90 ℃ of dryings two hours, get final product loosely the pale solid powder through grinding; Is 25% to be mixed with electrorheological fluid with this powdered sample and methyl-silicone oil by particle/silicone oil volume percent.The shear-stress of electrorheological fluid and strength of electric field relation are as shown in Figure 3.
Embodiment five: (washed kaolin electrorheological fluid)
With 150 ℃ down kaolin and the methyl-silicone oil after dry 2 hours be mixed with the washed kaolin electrorheological fluid by particle/silicone oil volume ratio 25%, the situation of measuring its shear-stress under different strength of electric field is as shown in Figure 1.
Embodiment six: (pure titanium oxide electrorheological fluid)
15 milliliters tetrabutyl titanates and 15 milliliters of dehydrated alcohols are mixed obtain light yellow transparent solution, stirring at room 5 hours, and then drip 2 milliliters of ethanolic solns that contain 0.2 milliliter of secondary deionized water, leave standstill after further fully stirring and can obtain opaque gel a night.This gel 80 ℃ of following vacuum-dryings 4 hours, again 90 ℃ of dryings two hours, can be obtained loose powdered through grinding, be final sample.Is 25% to be mixed with electrorheological fluid with sample and methyl-silicone oil by particle/silicone oil volume percent.The shear-stress of electrorheological fluid and the relation of strength of electric field are as shown in Figure 1.
Claims (5)
1. modified kaolin/titanium oxide Nano composite granules electro-rheologic fluid material and preparation method thereof, the disperse phase that it is characterized in that this material is modified kaolin/titanium oxide Nano composite granules, the external phase base fluid is a methyl-silicone oil; Prepare the process using sol-gel method of this discrete state material and the method that graft process combines.
2. according to the described modified kaolin of claim 1/titanium oxide Nano composite granules electro-rheologic fluid material and preparation method thereof, it is characterized in that dispersion particle is a kind of cladding nanometer composite particles, its nuclear is kaolin/sodium-chlor intercalated compound, utilizes sol-gel method to coat again and goes up titanium oxide.
3. according to the described modified kaolin of claim 1/titanium oxide Nano composite granules electro-rheologic fluid material and preparation method thereof, it is characterized in that kaolin/sodium-chlor intercalated compound is interacted by kaolin and dimethyl sulfoxide (DMSO) earlier, form the kaolin intercalated compound, sodium-chlor carries out the secondary intercalation replacement then, forms kaolin/sodium-chlor intercalated compound.Utilizing sol-gel method again serves as that nuclear coats upward titanium oxide with kaolin/sodium-chlor intercalated compound, forms the cladding nanometer matrix material.
4. according to the described modified kaolin of claim 1/titanium oxide Nano composite granules electro-rheologic fluid material and preparation method thereof, it is characterized in that modified kaolin/titanium oxide Nano composite granules 25% mixes with silicone oil that to obtain with modified kaolin/titanium oxide Nano composite granules be the electrorheological fluid of dispersion particle by volume.
5. according to the described modified kaolin of claim 1/titanium oxide Nano composite granules electro-rheologic fluid material and preparation method thereof, it is characterized in that preparation technology's method may further comprise the steps:
(1) select for use dimethyl sulfoxide (DMSO) to make presoma, 10g kaolin adds the 20ml dimethyl sulfoxide (DMSO) and reacted 8 hours down for 80 ℃, then one week of drying at room temperature, promptly gets the kaolin intercalated compound;
(2) then an amount of kaolin intercalated compound is joined in the saturated solution of sodium-chlor, this mixture and weight sodium chloride ratio are 1: 2, fully stir 8 hours, grind after boiling dry out solvent, pale powder.On the tabletting machine this powder is being depressed to thin slice about 5mm in 12MPa again.
(3) thin slice is through 100 ℃ of half an hour, 200 ℃ of half an hour, 300 ℃ of calcinings of 2 hours.The calcining sample is through grinding, and deionized water repeatedly washs, in filtrate not till the chloride ion-containing; Obtain kaolin/sodium-chlor intercalated compound after sample drying, the grinding.
(4) again 3g kaolin/sodium-chlor intercalated compound is joined in the 15ml dehydrated alcohol, at room temperature fully stir; Then 7ml tetrabutyl titanate and 7ml dehydrated alcohol are mixed, and under stirring condition, it is splashed in the alcohol suspension of kaolin/sodium-chlor intercalated compound, further fully stir; Splash into a certain amount of dehydrated alcohol that contains a small amount of secondary deionized water at last, stirring at room 5 hours; Again this system is left standstill and to obtain opaque gel a night; With this gel 80 ℃ dry 4 hours down, again 90 ℃ of dryings two hours, get final product loosely the pale solid powder through grinding; Is 25% to be mixed with electrorheological fluid with this powdered sample and methyl-silicone oil by particle/silicone oil volume percent.
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|---|---|---|---|
| CN 03114669 CN1228423C (en) | 2003-04-22 | 2003-04-22 | Current variable fluid material of modified Nano composite granules between kaoline and oxide of titanium, and prepration method |
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| CN 03114669 CN1228423C (en) | 2003-04-22 | 2003-04-22 | Current variable fluid material of modified Nano composite granules between kaoline and oxide of titanium, and prepration method |
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| CN1228423C CN1228423C (en) | 2005-11-23 |
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Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN108169308A (en) * | 2017-12-28 | 2018-06-15 | 中南大学 | A kind of preparation method and applications of clay modified electrode |
| CN108793784A (en) * | 2018-07-07 | 2018-11-13 | 河源市极致知管信息科技有限公司 | One kind containing kaolin composite material and preparation method thereof |
| CN110055126A (en) * | 2019-05-31 | 2019-07-26 | 青岛科技大学 | A kind of MOF-Ti/TiOx core-shell type nano composite particles ER fluid and preparation method thereof |
| CN116102057A (en) * | 2022-11-18 | 2023-05-12 | 山西工学院 | Titanium dioxide coated kaolin as well as preparation method and application thereof |
-
2003
- 2003-04-22 CN CN 03114669 patent/CN1228423C/en not_active Expired - Fee Related
Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN108169308A (en) * | 2017-12-28 | 2018-06-15 | 中南大学 | A kind of preparation method and applications of clay modified electrode |
| CN108169308B (en) * | 2017-12-28 | 2020-11-06 | 中南大学 | Preparation method and application of clay modified electrode |
| CN108793784A (en) * | 2018-07-07 | 2018-11-13 | 河源市极致知管信息科技有限公司 | One kind containing kaolin composite material and preparation method thereof |
| CN110055126A (en) * | 2019-05-31 | 2019-07-26 | 青岛科技大学 | A kind of MOF-Ti/TiOx core-shell type nano composite particles ER fluid and preparation method thereof |
| CN116102057A (en) * | 2022-11-18 | 2023-05-12 | 山西工学院 | Titanium dioxide coated kaolin as well as preparation method and application thereof |
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| CN1228423C (en) | 2005-11-23 |
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