CN1837043A - Rare earth particle and montmorillonite nano composite materials and process for preparing same - Google Patents

Rare earth particle and montmorillonite nano composite materials and process for preparing same Download PDF

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CN1837043A
CN1837043A CN 200610042687 CN200610042687A CN1837043A CN 1837043 A CN1837043 A CN 1837043A CN 200610042687 CN200610042687 CN 200610042687 CN 200610042687 A CN200610042687 A CN 200610042687A CN 1837043 A CN1837043 A CN 1837043A
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rare earth
montmorillonite
earth ion
nano composite
composite material
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CN100427392C (en
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莫尊理
张平
陈红
左丹丹
吴迎冰
牛贵平
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Northwest Normal University
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Abstract

The invention discloses a Rare earth particle/montmorillonite nanocomposite material and process for preparing, this method depending on surface activator. Self-assembling to produce template, taking polymer monomer as oil phase, Rare earth ionic solution as aqueous phase, mixing them to form contrary Rare earth nano particle, getting Rare earth particle equally dispersed in oil phase, forming thermodynamical steady emulsion system, intercalating the emulsion between layers of montmorillonite, joining initiator, polymer monomer carrying through home position polymerization directly, and then doing microwave radiation, breaking up polymer to CO and H2O, getting Rare earth particle/MMT nanocomposite material.

Description

Rare earth ion/Nanometer Composite Material Of Montmorillonite And Its Preparation Method
Technical field
The present invention relates to a kind of nano composite material, particularly a kind of rare earth ion/Nano composite material of montmorillonite based on polynite; The present invention also relates to a kind of method of utilizing the emulsion intercalation microwave method to prepare rare earth ion/Nano composite material of montmorillonite simultaneously.
Background technology
Polynite because aboundresources, inexpensive, have preferably that performances such as swelling property, cementability, adsorptivity, oilness and cationic exchange can be used as caking agent, absorption agent, weighting agent, catalyzer, washing composition, thickening material etc., be widely used in fields such as industrial or agricultural, medicine and environmental improvement, be called as " clay ", " omnipotent clay ", " lived mineral " with thousand kinds of purposes.
In recent years, the research of polynite intercalation compound is developed, and makes polynite have higher practicality.Because polynite singularity is widely used as the filler of thermal resistance polymer composites and conducting polymer composite material.Filler content is high more within the specific limits, and performance of composites is good more, but the mechanical property of material descends to some extent, and particularly toughness of material can obviously descend.An effective way that improves composite property is evenly to be filled in polymkeric substance with nano level inorganic particulate, can improve its thermal property, electric property and mechanical property, but adopt traditional blend method, be difficult to make the homodisperse on the filler acquisition nanometer level.Because the chemical structure and the physical aspect of filler and polymkeric substance differ bigger, at present, the interfacial energy that the interface modification technology is difficult to change fully between filler and polymeric matrix reduces interfacial tension, realizes nano level homodisperse and bonding interface.Therefore matrix material does not reach the molecular dispersion level, and only belongs to the microcosmic mixing material, has influenced the improvement of the due toughness of material, rigidity, thermotolerance and electric property.Improved approach is each phase homodisperse and form matrix material.Owing to there is very strong bonding force between montmorillonite layer, be easy to generate to cover and take off ± the lamella gathering, cause the ununiformity of compound system middle-weight rare earths particle, exceed nano level, no longer be nano composite material, thereby influence performance of composites greatly.Can not be dispersed in the montmorillonite layer with nano level and influence matrix material in order to solve prior art middle-weight rare earths particle.In the polymerization process of matrix material, rely on tensio-active agent to form microemulsion, the isotropy of spontaneous formation, Thermodynamically stable, appearance transparent or translucent colloid emulsion, produce reverse micelle " pond reacting field ", this " microreactor " space can synthesis nano particulate, need not to carry out organically-modified and redispersion in presoma to inorganic nano-particle, directly intercalation carries out the body in-situ polymerization, carry out microwave radiation then and make rare earth ion/MMT nano composite material, both overcome rare earth ion homodisperse difficult problem in montmorillonite layer, simplified technology again.Have only montmorillonite layer and rare earth ion that strong interaction is arranged, and reach the dispersion of nanoscale, just the synergetic property of the two effectively may be brought into play, make it to become combination ideally, the good nano composite material of obtained performance.
Summary of the invention
The purpose of this invention is to provide a kind of rare earth ion/Nano composite material of montmorillonite;
Another object of the present invention provides a kind of method of utilizing the emulsion intercalation microwave technology to prepare rare earth ion/Nano composite material of montmorillonite.
Rare earth ion/Nano composite material of montmorillonite of the present invention is rare earth ion and montmorillonite layer homodisperse, combines closely; Wherein the particle diameter of rare earth ion is 20~30nm, and the thickness of montmorillonite layer is 30~50nm.
The pbw of described rare earth ion and polynite is: 1~20 part of rare-earth nanometer particles, 1~30 part of polynite.
Described rare-earth nanometer particles is the rare earth oxide particle.
The preparation method of rare earth ion/Nano composite material of montmorillonite of the present invention, be that a certain amount of polymer monomer is dissolved in the dispersion agent that is dissolved with tensio-active agent, stir to wherein adding a certain amount of rare earth salt aqueous solution, at room temperature ultra-sonic dispersion is 30~60 minutes, forms the reverse micelle emulsion again; Then at N 2Protection dropwise joins the reverse micelle emulsion in the organo montmorillonite aqueous dispersions down, attemperation to 60~80 ℃, magnetic agitation was disperseed intercalation 2~3 hours, add an amount of initiator subsequently and make the polymer monomer initiated polymerization, react after 15~30 hours and to add the acclimatization agent rare earth ion is precipitated fully, filter, wash vacuum drying; Be the microwave radiation 0.2~1.5 hour of 2000~2500MHz with frequency then, make polymer unwinds become CO 2And H 2O, microwave radiation is not obvious to rare earth ion crystallization influence, and resistant to elevated temperatures polynite remains unchanged, and makes rare earth ion/Nano composite material of montmorillonite.
The polymer monomer that present method adopts is any in aniline, methyl methacrylate, methyl acrylate, pyrroles or the O-Phenylene Diamine.
The tensio-active agent that present method adopts is anion surfactant, cats product or nonionogenic tenside; Wherein anion surfactant is sodium lauryl sulphate, sodium stearate or stearic acid; Cats product is a palmityl trimethyl ammonium chloride; Nonionogenic tenside is an alkylphenol polyoxyethylene.The add-on of tensio-active agent is 15~25% of a polymer monomer weight.
The existence of tensio-active agent prepares the rare-earth nanometer particles that is uniformly dispersed at self-assembly formation reverse micelle microemulsion on the one hand and plays an important role, again as the coating materials of polynite and rare-earth nanometer particles, improved oil phase and water consistency and avidity.Emulsion is the translucent colloidal dispersion system of isotropy, Thermodynamically stable, outward appearance that relies on the spontaneous formation of tensio-active agent." pond reacting field " in the emulsion is nano level, size is little and be evenly distributed, limited the growing space of nanoparticle effectively, make water and oil phase in reaction process, be uniformly dispersed, the rare earth ion of aqueous phase is with regard to being tied in the polymkeric substance and keep original homodisperse state when polymer monomer generation polymerization, carry out microwave radiation then and make rare earth ion/MMT nano composite material, solved the agglomeration traits of nanoparticle effectively, and reach the homodisperse of nanoscale, make nano composite material have the unapproachable premium properties of many employing traditional methods.
The dispersion medium that the present invention adopts is trichloromethane, water or ethanol.The amount of dispersion medium is 4~10 times of polymer monomer quality.The effect of dispersion medium is to promote the dispersion of polynite in polymer monomer.Dispersion medium is decided according to monomer, rare earth ion, initiator.Good dispersion medium should make polynite and rare-earth nanometer particles disperse easily and have good miscibility with monomer and initiator, and the composite property of preparing is good.
The rare-earth salts that the present invention adopts is the nitrate or the muriate of soluble ree; Wherein the add-on of rare-earth salts is 1~20% of a polymer monomer quality.
The organo montmorillonite that the present invention adopts is to be organic modifiers with cetyl trimethylammonium bromide, Dodecyl trimethyl ammonium chloride or octadecyl trimethylammonium bromide, carries out natural montmorillonite organically-modified and gets; The add-on of organo montmorillonite is 1~30% of a polymer monomer quality.
The method of modifying of organo montmorillonite is: a certain amount of properties-correcting agent is placed water, add appropriate hydrochloric acid and regulate the protonated solution of formation; The polynite that to purify in right amount places water again, in 40~60 ℃ water bath with thermostatic control, leave standstill behind stirring heating 30~60min, form the polynite aqueous dispersions, then above-mentioned protonated solution is dropwise joined in the polynite aqueous dispersions, and with vibration of ultrasonic wave 3~4 hours, again through suction filtration and wash with water and only do not have bromide anion and chlorion, at last under 70~90 ℃, through vacuum-drying, grind, sieve after, product be organo montmorillonite.The lamella of this organo montmorillonite is evenly dispersed in the organic modifiers matrix, the thickness of lamella is 40~50nm, sheet interlayer spacing is 3~15nm, and this special structure of organo montmorillonite is for the nanofeature for preparing rare earth ion/Nano composite material of montmorillonite provides basis.
The initiator that the present invention adopts is Diisopropyl azodicarboxylate, ammonium persulphate or p-methyl benzenesulfonic acid iron; The add-on of initiator is 0.1~320% of a polymer monomer quality, determines according to polymer monomer.
The precipitation agent that the present invention adopts is a sodium hydroxide.
The present invention compared with prior art has the following advantages:
1, rare earth ion/Nano composite material of montmorillonite of the present invention, make the thickness of montmorillonite layer be approximately 30~50nm, can find out significantly that the polynite after expanding is keeping peeling off phenomenon on original laminate structure basis, formed regular nano composite material, the median size of rare-earth nanometer particles is about 25nm, has very large interfacial area, rare earth ion and polynite basal body interface have the ideal adhesiveproperties, can eliminate two material thermal expansivity and not match and immiscible problem, make that the physicochemical property of matrix material is well improved.
2, preparation method of the present invention is template with the tensio-active agent, the formation of rare-earth nanometer particles and the preparation of matrix material are carried out synchronously, and water and oil phase are uniformly dispersed in reaction process, when in the emulsion during monomer generation polymerization rare earth ion with regard to being tied in the polymkeric substance and keep original homodisperse state, carry out microwave radiation for some time polymer unwinds CO in microwave then 2And H 2O, microwave radiation is not obvious to rare earth ion crystallization influence, and resistant to elevated temperatures polynite remains unchanged, solved the agglomeration traits of nanoparticle effectively, and reach the homodisperse of nanoscale, thereby effective simplification the Composite Preparation program, shortened preparation time.Method of the present invention is simple to operate, the production efficiency height, and cost is low, and is convenient to suitability for industrialized production.
Description of drawings
Fig. 1 is that rare earth ion of the present invention/Nano composite material of montmorillonite forms synoptic diagram
Fig. 2 is rare earth ion of the present invention/Nano composite material of montmorillonite SEM photo
Fig. 3 is the XRD figure of rare earth ion/Nano composite material of montmorillonite of the present invention
(a) is that matrix material amplifies 6.2 * 10 among Fig. 2 4The SEM photo, can be clear that dispersive rare-earth nanometer particles on the structure of polynite and the lamella; (b) be the SEM photo figure of one of them lamella, can clearly see equally and disperse rare-earth nanometer particles on the montmorillonite layer uniformly.The thickness that can estimate montmorillonite layer from figure (a) is approximately 30~50nm, and is bigger than the thickness of former MMT lamella, and this is because the CO that produces during polymer unwinds on the montmorillonite layer 2And H 2O causes the swollen shape of polynite.Can find out significantly that by figure (a) montmorillonite layer has kept its original laminate structure substantially, rare earth ion has all inserted its interlayer, form regular rare earth ion/MMT nano composite material, rare earth ion combines with montmorillonite layer closely as can be seen, should have adsorption between them.Can see significantly that by figure (b) distribution of rare-earth nanometer particles between montmorillonite layer is more even, and particle diameter is less, median size is about 25nm, can think that thus the nanoparticle of matrix material is to carry out in reverse micelle microemulsion " pond reacting field ", emulsion " microreactor " size is little and be evenly distributed, make water and oil phase in reaction process, be uniformly dispersed, inorganic phase rare earth nano ion has limited the reunion and the growth of nanoparticle with regard to being tied in the organism and keep original homodisperse state when organism generation polymerization.And in microwave polymer unwinds CO 2And H 2O, resistant to elevated temperatures rare earth ion and polynite remain unchanged, and have effectively solved the agglomeration traits of nanoparticle, make rare earth ion/MMT nano composite material.
Among Fig. 3, (a) being the XRD figure of MMT, (b) is Pr 2O 3The XRD figure of/MMT nano composite material (c) is the XRD figure of polymkeric substance/rare earth ion/MMT nano composite material.According to Bragg equation 2dsin θ=n λ as can be known, the angle of diffraction peak correspondence reduces, and the interlamellar spacing of polynite increases.(c) compares as can be known with (a) among Fig. 3, the diffraction peak of polymkeric substance/rare earth ion/MMT nano composite material ° place correspondence in 2 θ=7.2 disappears with respect to the diffraction peak of simple MMT, further increase and ° locate to have occurred this explanation montmorillonite layer spacing of diffraction peak in 2 θ=2.1, polymkeric substance has inserted the interlayer of polynite.(a) and (b) are compared as can be known with (c) among Fig. 3, (b) ° locate to have occurred diffraction peak in 2 θ=2.6, show the interlamellar spacing of rare earth ion/MMT nanometer composite layer spacing less than polymkeric substance/rare earth ion/MMT nano composite material, and greater than the interlamellar spacing of MMT, compare with (a) (b) and (c) in 2 θ=12.5 ° and 2 θ=27.6 ° locate all to have occurred new diffraction peak, illustrate and inserted rare earth ion in the polynite simultaneously, the intensity of diffraction peak says that more by force the rare earth ion crystallization in bright this matrix material is better.More than analyze explanation polymer unwinds CO in microwave 2And H 2O makes interlamellar spacing reduce to some extent, microwave radiation is not obvious to rare earth ion crystallization influence, and resistant to elevated temperatures polynite remains unchanged, and rare earth ion has inserted between cheating engaging layer, effectively solve the agglomeration traits of nanoparticle, made rare earth ion/MMT nano composite material.
Embodiment
Embodiment 1,100 parts of aniline, 15 parts of sodium lauryl sulphate joined in 400 parts the water and stir; Rare earth Nd with 20 parts 2O 3Be dissolved in the NdCl that hydrochloric acid is mixed with 0.1mol/L 3The aqueous solution, and join in the above-mentioned mixing solutions, at room temperature ultra-sonic dispersion is 30 minutes, forms the reverse micelle emulsion.With 1 fen weight through purify, organically-modified polynite places water, leaves standstill behind 40~60 ℃ of homothermic stirred in water bath heating 30~60min, forms the polynite aqueous dispersions; Then at N 2Protection dropwise joins the reverse micelle emulsion in the organo montmorillonite aqueous dispersions down, attemperation to 60 ℃, and magnetic agitation was disperseed intercalation 2 hours.Cooling subsequently moves to reactant in the ice-water bath about 2 ℃ and dropwise to add 100 parts of ammonium sulfate initiators, makes the polymer monomer initiated polymerization, react after 15 hours, add the NaOH solution of 0.3mol/L, rare earth ion is precipitated fully, filter, wash vacuum drying; Be the microwave radiation 0.2 hour of 2000MHz with frequency then, make polymer unwinds become CO 2And H 2O makes Nd 2O 3/ MMT nano composite material.
Embodiment 2,100 parts of methyl methacrylates, 18 parts of sodium stearate joined in 500 parts the trichloromethane and stir; Rare earth Nd with 15 parts 2O 3Be dissolved in the EuCl that hydrochloric acid is mixed with 0.1mol/L 3The aqueous solution, and join in the above-mentioned mixing solutions, at room temperature ultra-sonic dispersion is 35 minutes, forms the reverse micelle emulsion; Place water with 6 parts through purification, organically-modified polynite, behind 40~60 ℃ of homothermic stirred in water bath heating 30~60min, leave standstill, form the polynite aqueous dispersions; Then at N 2Protection dropwise joins the reverse micelle emulsion in the organo montmorillonite aqueous dispersions down, attemperation to 65 ℃, magnetic agitation was disperseed intercalation 2.5 hours, add 0.001 part of Diisopropyl azodicarboxylate subsequently, make the polymer monomer initiated polymerization, react the NaOH solution that adds 0.3mol/L after 18 hours, rare earth ion is precipitated fully, filter, wash vacuum drying; Be the microwave radiation 0.5 hour of 2200MHz with frequency then, make polymer unwinds become CO 2And H 2O makes Nd 2O 3/ Nano composite material of montmorillonite.
Embodiment 3,100 parts of methyl acrylates, 20 parts of stearic acid joined in 700 parts the ethanol and stir; Rare earth La with 10 parts 2O 3Be dissolved in the LaCl that hydrochloric acid is mixed with 0.1mol/L 3The aqueous solution, and join in the above-mentioned mixing solutions, at room temperature ultra-sonic dispersion is 40 minutes, forms the reverse micelle emulsion; Place water with 12 parts through purifying and carrying out organically-modified polynite, behind 40~60 ℃ of homothermic stirred in water bath heating 30~60min, leave standstill, form the polynite aqueous dispersions; Then at N 2Protection dropwise joins the reverse micelle emulsion in the organo montmorillonite aqueous dispersions down, attemperation to 70 ℃, magnetic agitation was disperseed intercalation 3 hours, adding 1 part of Diisopropyl azodicarboxylate subsequently is initiator, make the polymer monomer initiated polymerization, react the NaOH solution that adds 0.3mol/L after 20 hours, rare earth ion is precipitated fully, filter, wash vacuum drying; Be the microwave radiation 0.7 hour of 2100MHz with frequency then, make polymer unwinds become CO 2And H 2O makes La 2O 3/ Nano composite material of montmorillonite.
Embodiment 4,100 parts of pyrroles, 22 parts of palmityl trimethyl ammonium chlorides joined in 900 parts the trichloromethane and stir; Rare-earth salts Pr with 5 parts 2(CO 3) 3Be dissolved in nitric acid and be mixed with 0.1mol/LPr (NO 3) 3The aqueous solution, and join in the above-mentioned mixing solutions, at room temperature ultra-sonic dispersion is 45 minutes, forms the reverse micelle emulsion; Place water with 25 parts through purifying and carrying out organically-modified polynite, behind 40~60 ℃ of homothermic stirred in water bath heating 30~60min, leave standstill, form the polynite aqueous dispersions; Then at N 2Protection dropwise joins the reverse micelle emulsion in the organo montmorillonite aqueous dispersions down, attemperation to 75 ℃, and magnetic agitation was disperseed intercalation 2.5 hours.Cooling subsequently moves to reactant in the ice-water bath about 2 ℃, dropwise adds 150 parts of p-methyl benzenesulfonic acid iron initiators, makes the polymer monomer initiated polymerization, react the NaOH precipitation agent that adds 50 weight parts after 25 hours, filters, washs vacuum drying; Be the microwave radiation 1 hour of 2300MHz with frequency then, make polymer unwinds become CO 2And H 2O makes Pr 2O 3/ Nano composite material of montmorillonite.
Embodiment 5,100 parts of O-Phenylene Diamines, 25 parts of alkylphenol polyoxyethylene joined in 1000 parts the ethanol and stir; Rare earth Eu with 1 part 2O 3Be dissolved in the aqueous solution that hydrochloric acid is mixed with 0.1mol/L, and join in the above-mentioned mixing solutions, at room temperature ultra-sonic dispersion is 30 minutes, forms the reverse micelle emulsion; Place water with 30 through purifying and carrying out organically-modified polynite, behind 40~60 ℃ of homothermic stirred in water bath heating 30~60min, leave standstill, form the polynite aqueous dispersions; Then at N 2Protection dropwise joins the reverse micelle emulsion in the organo montmorillonite aqueous dispersions down, attemperation to 60 ℃, and magnetic agitation was disperseed intercalation 2 hours.Cooling subsequently moves to reactant that dropwise to add 100 parts of ammonium persulphates in the ice-water bath about 2 ℃ be initiator, makes the polymer monomer initiated polymerization, react the NaOH solution that adds 0.3mol/L after 15 hours, rare earth ion is precipitated fully, filter, wash vacuum drying; Be the microwave radiation 1.5 hours of 2500MHz with frequency then, make polymer unwinds become CO 2And H 2O makes Eu 2O 3/ MMT nano composite material.

Claims (10)

1, a kind of rare earth ion/Nano composite material of montmorillonite is characterized in that: the particle diameter of rare earth ion is 20~30nm, and the thickness of montmorillonite layer is 30~50nm, and rare earth ion and montmorillonite layer are uniformly dispersed and combine closely.
2, a kind of rare earth ion/Nano composite material of montmorillonite as claimed in claim 1, it is characterized in that: the pbw of described rare earth ion and polynite is: 1~20 part of rare-earth nanometer particles, 1~30 part of polynite.
3, a kind of rare earth ion/Nano composite material of montmorillonite as claimed in claim 1 is characterized in that: described rare-earth nanometer particles is the oxide compound of rare earth.
4, a kind of preparation method of rare earth ion/Nano composite material of montmorillonite, be that a certain amount of polymer monomer is dissolved in the dispersion agent that is dissolved with tensio-active agent, stir to wherein adding a certain amount of rare earth salt aqueous solution, at room temperature ultra-sonic dispersion is 30~60 minutes, forms the reverse micelle emulsion again; Under the N2 protection, the reverse micelle emulsion is dropwise joined in the organo montmorillonite aqueous dispersions then, attemperation to 60~80 ℃, magnetic agitation was disperseed intercalation 2~3 hours, add an amount of initiator subsequently and make the polymer monomer initiated polymerization, react after 15~30 hours and to add the acclimatization agent rare earth ion is precipitated fully, filter, wash vacuum drying; Be the microwave radiation 0.2~1.5 hour of 2000~2500MHz with frequency then, make polymer unwinds become CO2 and H2O, make rare earth ion/Nano composite material of montmorillonite.
5, as the preparation method of rare earth ion/Nano composite material of montmorillonite as described in the claim 4, it is characterized in that: described polymer monomer is any in aniline, methyl methacrylate, methyl acrylate, pyrroles or the O-Phenylene Diamine.
6, as the preparation method of rare earth ion/Nano composite material of montmorillonite as described in the claim 4, it is characterized in that: described tensio-active agent is anion surfactant, cats product or nonionogenic tenside; Wherein anion surfactant is sodium lauryl sulphate, sodium stearate or stearic acid; Cats product is a palmityl trimethyl ammonium chloride; Nonionogenic tenside is an alkylphenol polyoxyethylene; The add-on of tensio-active agent is 15~25% of a polymer monomer weight.
7, as the preparation method of rare earth ion/Nano composite material of montmorillonite as described in the claim 4, it is characterized in that: described dispersion medium is trichloromethane, water or ethanol; The amount of dispersion medium is 4~10 times of polymer monomer quality.
8, as the preparation method of rare earth ion/Nano composite material of montmorillonite as described in the claim 4, it is characterized in that: described rare-earth salts is the nitrate or the muriate of soluble ree; Wherein the add-on of rare-earth salts is 1~20% of a polymer monomer quality.
9, as the preparation method of rare earth ion/Nano composite material of montmorillonite as described in the claim 4, it is characterized in that: described initiator is Diisopropyl azodicarboxylate, ammonium persulphate or p-methyl benzenesulfonic acid iron; The add-on of initiator is 0.1~320% of a polymer monomer quality.
10, as the preparation method of rare earth ion/Nano composite material of montmorillonite as described in the claim 4, it is characterized in that: described precipitation agent is a sodium hydroxide.
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CN108164902A (en) * 2018-01-26 2018-06-15 中山职业技术学院 Modified montmorillonite used dispersion liquid, 3D printing dusty material and preparation method thereof
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