WO2012068764A1 - 一种微细平直pzt压电纤维阵列的制备方法 - Google Patents
一种微细平直pzt压电纤维阵列的制备方法 Download PDFInfo
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- WO2012068764A1 WO2012068764A1 PCT/CN2010/080554 CN2010080554W WO2012068764A1 WO 2012068764 A1 WO2012068764 A1 WO 2012068764A1 CN 2010080554 W CN2010080554 W CN 2010080554W WO 2012068764 A1 WO2012068764 A1 WO 2012068764A1
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- OERNJTNJEZOPIA-UHFFFAOYSA-N zirconium nitrate Chemical compound [Zr+4].[O-][N+]([O-])=O.[O-][N+]([O-])=O.[O-][N+]([O-])=O.[O-][N+]([O-])=O OERNJTNJEZOPIA-UHFFFAOYSA-N 0.000 claims description 28
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- YHWCPXVTRSHPNY-UHFFFAOYSA-N butan-1-olate;titanium(4+) Chemical compound [Ti+4].CCCC[O-].CCCC[O-].CCCC[O-].CCCC[O-] YHWCPXVTRSHPNY-UHFFFAOYSA-N 0.000 claims description 14
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Definitions
- the invention relates to a functional ceramic fiber and a manufacturing method thereof, in particular to a method for manufacturing a fine flat PZT piezoelectric fiber array.
- the piezoelectric fiber arrays are basically obtained by arranging the piezoelectric fibers. This method is effective for arrays of coarse fibers, but for fine fibers, especially those having a diameter of less than several hundred micrometers. Since it is easy to cause fiber breakage and disorder of the array during the operation, it is extremely disadvantageous to use the alignment method to obtain the array.
- a preparation method of a micro-flat PZT piezoelectric fiber array characterized in that: using a plastic capillary as a reaction template, first preparing a PZT sol, then adding PZT nano powder, mixing uniformly to form a suspension, and cutting the plastic capillary into an appropriate length
- a container that is open at both ends and can be used in the PZT sintering temperature range, the gap between the capillary and the gap between the container and the plastic capillary are filled with glue or paraffin and solidified into a desired array shape, which is filled with a plastic capillary.
- the container is immersed in the suspension, and after sufficient adsorption, the remaining suspension is poured from one end of the container, and filtered at the other end, so that the suspension containing the nano PZT powder is pumped into the plastic capillary tube. Until the capillary is filled with the suspension; the container containing the plastic capillary is dried to no excess liquid component, and the multiple times of immersion, suction filtration, and drying are taken out, and the dried plastic capillary-containing container is subjected to template removal and crystallization. Heat treatment to obtain a PZT piezoelectric fiber array structure.
- the method for preparing a fine flat PZT piezoelectric fiber array is characterized in that: the PZT sol is prepared as follows: lead acetate, zirconium nitrate and tetrabutyl titanate are uniformly mixed in a solvent and a stabilizer, and then water is added. The mixture was reacted with acetic acid under a low temperature heating and ultrasonic vibration at 80 ° C, and stirred uniformly on a magnetic stirrer to obtain the sol.
- the preparation method of the fine flat PZT piezoelectric fiber array is characterized in that the preparation method of the sol-powder mixing system is as follows: mixing the PZT sol and the nano PZT powder, adding PEG as a dispersing agent, and lowering at 80 ° C. The mixture was uniformly stirred under heating, and ultrasonically dispersed to uniformly mix the mixture with the sol.
- the method for preparing a fine flat PZT piezoelectric fiber array is characterized in that the solvent is ethylene glycol monomethyl ether and the stabilizer is acetylacetone.
- the method for preparing a fine flat PZT piezoelectric fiber array is characterized in that: the weight ratio of the PZT sol and the nano PZT powder is 1:0.05 to 1:0.5; the PZT sol comprises lead acetate, zirconium nitrate, The concentration of PZT sol is 0.2-1.0 mol/l, and the ratio of the amount of lead acetate, zirconium nitrate and tetrabutyl titanate is 100: (50-60): (40) ⁇ 48), the weight ratio of water to acetic acid is 1:0.5 to 1:2.
- the method for preparing a fine flat PZT piezoelectric fiber array is characterized in that the ratio of the amount of the lead acetate, zirconium nitrate and tetrabutyl titanate is 100:56:44.
- the method for preparing a fine flat PZT piezoelectric fiber array is characterized in that the weight ratio of water to acetic acid is 1:1.
- the method for preparing a fine flat PZT piezoelectric fiber array is characterized in that the concentration of the sol is 0.35 Mol/l.
- the method for preparing a fine flat PZT piezoelectric fiber array is characterized in that the weight ratio of the PZT sol and the PZT powder is 1:0.1.
- the method for preparing a fine flat PZT piezoelectric fiber array is characterized in that the weight ratio of the nano PZT powder to PEG is 1:0.001 ⁇ 1:0.008.
- the method for preparing a fine flat PZT piezoelectric fiber array is characterized in that the weight ratio of the nano PZT powder to PEG is 1:0.005.
- the method for preparing a fine flat PZT piezoelectric fiber array is characterized in that: the process of template removal and crystallization heat treatment is: room temperature ⁇ 200 ° C, heating rate 1 ° C / min, 200 ° C heat preservation 1 h ; 200 ⁇ 600°C, heating rate 2°C/min, 600°C insulation 1 ⁇ 2h; 600°C ⁇ 950°C, heating rate 3.5°C/min, heat preservation for 30 minutes.
- the method for preparing a fine flat PZT piezoelectric fiber array is characterized in that the container is a quartz tube.
- the outstanding advantage of the invention is that the method can precisely control the diameter and length of the fiber, and can prepare a diameter of only a few micrometers to several hundred micrometers and a length of 0.5 cm to 3 cm, which is straight.
- PZT micro piezoelectric fiber with high density the PZT piezoelectric fiber has a single perovskite phase structure, and the surface is smooth and has high piezoelectric property.
- the piezoelectric fiber prepared by the method can be directly arranged without manual arrangement. Various desired array structures are formed, the fibers are arranged neatly and orderly, and the damage is small.
- Figure 2 is a scanning electron micrograph of PZT piezoelectric fiber after sintering at 950 °C.
- the fiber morphology shows that the fiber is dense and has no pores.
- Fig. 3 is a scanning electron micrograph of a PZT piezoelectric fiber array sintered at 950 ° C. The fibers are arranged neatly in order and have less damage.
- the invention relates to a PZT piezoelectric fiber and an array structure thereof, which are characterized in that a fine flat PZT ceramic fiber array is prepared by using a plastic capillary tube as a template and a sol-PZT nano powder blending adsorption and reaction method.
- the ratio of the sol and the nano PZT powder is 1:0.05 ⁇ 1:0.5; the sol comprises lead acetate, zirconium nitrate, tetrabutyl titanate, water, acetic acid, and the concentration of the sol is 0.2-1.0 mol/l, wherein lead acetate and nitric acid are contained therein.
- the ratio of zirconium and tetrabutyl titanate is 100: (50 to 60): (40 to 48), and the ratio of water to acetic acid is 1:0.5 to 1:2.
- the preparation method of the PZT piezoelectric fiber of the invention is carried out according to the following processes:
- PZT sol preparation the ratio of lead acetate, zirconium nitrate, tetrabutyl titanate in a solvent and a stabilizer is mixed with the above ratio of water and acetic acid, under low temperature heating and ultrasonic vibration at 80 ° C Mixing the mixture uniformly, stirring uniformly on a magnetic stirrer and completely generating a hydrolysis reaction to obtain the sol;
- sol-powder mixing system mixing the sol and the nano PZT powder in the above-mentioned ratio, adding PEG as a dispersing agent, heating and uniformly stirring at a low temperature of 80 ° C, and ultrasonically dispersing to make the mixture and the sol fully mixed uniformly;
- PZT piezoelectric fiber Cut the plastic capillary into appropriate length, fill the gap between the capillary with glue or paraffin and solidify into a certain array shape, placed in the quartz tube, the gap between the quartz tube and the plastic capillary. Partly sealed with glue or paraffin. First, the quartz tube containing the plastic capillary tube is immersed in the obtained suspension, and after sufficient adsorption, the resulting suspension is slowly poured from the upper part of the quartz tube, and suction-filtered underneath, so that the nano PZT powder enters through the pumping force.
- the quartz tube and the plastic capillary tube are placed in an oven at 60 ° C to dry to no excess liquid component, and the extraction is repeated multiple times, suction filtration, and drying several times;
- the solvent of the PZT piezoelectric fiber of the present invention and the method for producing the same is characterized in that the solvent in the sol is ethylene glycol monomethyl ether, and the stabilizer is acetylacetone.
- the method for manufacturing the novel PZT piezoelectric fiber array of the present invention has a ratio of lead acetate, zirconium nitrate and tetrabutyl titanate of 100: (50 to 60): (40 to 48), and an optimum ratio of 100:56:44;
- the powders are all nano PZT powder.
- the method for producing PZT piezoelectric fiber of the present invention has a water to acetic acid ratio of 1:0.5 to 1:2, and the ideal ratio is 1:1. If the ratio is too large, the water is too high, the hydrolysis rate of the sol is faster, and the gel loses fluidity. On the contrary, the ratio is too small, and the content of acetic acid is too high, although it is beneficial to inhibit the progress of hydrolysis, but During the drying and firing process, acetic acid volatilizes, expanding the shrinkage of the fibers, while leaving a large number of pores, reducing the density and strength of the fibers, thus requiring a ratio of water to acetic acid within the stated range.
- the method for producing a PZT piezoelectric fiber of the present invention has a sol concentration of 0.2 to 1.0 mol/l and an ideal concentration of 0.35 Mol/l. If the concentration is too high, the viscosity of the sol is too large, and the PZT nanopowder is not easily dispersed; if the concentration is too low, the density of the prepared fiber is affected, so the sol concentration is required to be within a certain range.
- the method for producing PZT piezoelectric fiber of the invention has a ratio of sol to PZT powder of 1:0.05 to 1:0.5, and an ideal ratio of 1:0.1.
- the ratio is too high, the solid phase content is low, the viscosity is too low, and the fiber is formed. It is easy to deform, and the ratio is too low.
- the sol powder system has poor fluidity and is easy to block the template. Therefore, the ratio of the sol and PZT powder is required to be within the above range.
- the weight ratio of the nano PZT powder to the PEG of the invention is 1:0.001 ⁇ 1:0.008, and the ideal ratio is 1:0.005.
- the ratio is too large, the easy formation of micelles is unfavorable for the dispersion of the nano powder in the sol, when the ratio is excessive It is less difficult to achieve the purpose of dispersing the powder well, and therefore, the ratio of the powder to the PEG is required to be within the above range.
- the method for producing the PZT piezoelectric fiber of the present invention is as follows: 1. Room temperature ⁇ 200 ° C, heating rate 1 ° C / min, 200 ° C for 1 h, mainly in the fiber precursor water and some organic matter volatilization; 200 ⁇ 600°C, heating rate 2°C/min, 600°C for 1 ⁇ 2h, mainly for volatilization and decomposition of organic matter and crystallization of PZT fiber; 3. 600°C ⁇ 950°C, heating rate 3.5°C/ Min, mainly for grain growth, fiber densification and venting, and holding for 30 minutes.
- Adjust the solution concentration to 0.3mol/l obtain the sol, take 10 parts of the sol, weigh 1 part of PZT nano-powder according to the weight ratio of sol:PZT powder: 1:0.1, then add PEG1000, add 0.5% of PZT nano-powder After dispersing for half an hour under magnetic stirring, it was dispersed in an ultrasonic disperser for 2 hours to prepare a sol powder system, and a thin-walled plastic capillary having an inner diameter of 0.25 mm was cut into a length of 2 cm, and 50 pieces were arranged in a circular cross-sectional array shape. The gap between the capillaries was filled with paraffin, placed in a quartz tube with an inner diameter of 1 cm, and solidified at room temperature for 30 minutes.
- the quartz tube and the fiber-containing plastic capillary tube were placed in a heat treatment furnace and calcined to 950 ° C for template. With the removal and sintering of the paraffin, PZT piezoelectric fibers having an average diameter of about 50 ⁇ m and a length of about 0.8 cm and a structure in which the circular cross-sectional arrays are arranged neatly are obtained.
- Example 2 Weigh the lead acetate, zirconium nitrate and tetrabutyl titanate in a molar ratio of 100:56:44, dissolve and mix with ethylene glycol monomethyl ether, add 1:1 water and acetic acid under magnetic stirring. Adjust the concentration of the solution to 0.5mol/l, obtain the sol, take 100 parts of the sol, weigh 6 parts of PZT nano powder according to the weight ratio of sol:PZT powder: 1:0.06, then add PEG400 and PEG2000, and add PZT nano powder. 0.6%, disperse for half an hour under magnetic stirring, and then disperse in an ultrasonic disperser for 2 hours to prepare a sol powder system.
- the thin-walled plastic capillary with an inner diameter of 0.3 mm was cut into a length of 4 cm, and 100 pieces were arranged in a circular cross-sectional array. Shape, fill the gap between the capillaries with 501 million rubber in a quartz tube with an inner diameter of 2cm, cure at room temperature for 6 hours, and then seal the gap between the quartz tube and the plastic capillary with a small amount of 501 million adhesive, and place the quartz with plastic capillary.
- the tube is immersed in the suspension obtained by mixing the above sol powders, and after being sufficiently adsorbed, the suspension is slowly poured from the upper part of the quartz tube and filtered underneath to allow the nano PZT powder to enter the plastic capillary by suction.
- the quartz tube and the plastic capillary are placed in an oven at 60 ° C to dry to no excess liquid component, and the multiple times of immersion, suction filtration, and drying are repeated several times, and the quartz tube is combined with the fiber-containing plastic.
- the capillary was placed in a heat treatment furnace and calcined to 1000 ° C to remove and sinter the template and the glue, and a PZT piezoelectric fiber having an average diameter of about 80 ⁇ m and a length of about 1.5 cm and a structure in which the circular cross-sectional array was arranged neatly were obtained.
- Example 3 Weigh the lead acetate, zirconium nitrate and tetrabutyl titanate in a molar ratio of 100:56:44, dissolve and mix with ethylene glycol monomethyl ether, add 1:1 water and acetic acid under magnetic stirring. Adjust the solution concentration to 0.35mol/l, obtain the sol, take 10 parts of the sol, weigh 4 parts of PZT nano powder according to the weight ratio of sol:PZT powder: 1:0.4, then add PEG1000, the weight is 0.5% of PZT nano powder. After dispersing for half an hour under magnetic stirring, it was dispersed in an ultrasonic disperser for 2 hours to prepare a sol powder system.
- the thin-walled plastic capillary with an inner diameter of 0.1 mm was cut into a length of 2 cm, and 49 pieces were arranged into 7 ⁇ 7 roots.
- the quartz tube is immersed in the suspension obtained by mixing the above sol powder. After being sufficiently adsorbed, the suspension is slowly poured from the upper part of the quartz tube and filtered underneath to allow the nano PZT powder to enter the plastic capillary by suction.
- the quartz tube and the plastic capillary tube are placed in an oven at 60 ° C to dry to no excess liquid component, and the multiple times of immersion, suction filtration, and drying are repeated several times, and the quartz tube is combined with the fiber-containing plastic capillary tube. It was placed in a heat treatment furnace and calcined to 950 ° C to remove and sinter the template and the glue to obtain a 7 ⁇ 7 PZT piezoelectric fiber square array structure having an average diameter of about 30 ⁇ m and a length of about 0.8 cm.
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Description
本发明涉及功能性陶瓷纤维及其制造方法,具体为一种微细平直PZT压电纤维阵列的制造方法。
压电纤维及其阵列结构因具有较高的压电应变常数和厚度机电耦合系数、低的机械品质因数和声阻抗等优异性能在传感器、驱动器、超声传感器装置以及汽车、航空等领域有着很大的潜在应用。
目前制备压电纤维常用的方法有溶胶-凝胶法、挤压法、纺丝法、拉拔法、机械切割法、基体纤维浸渍法等。如美国Advanced
Cerametrics公司采用悬浮磁粉纺丝法制备了横断面尺寸在80~300μm的PZT纤维,但由于该方法使用大量的有机高分子作为载体,导致纤维经热解和烧结后内部有较多空隙,纤维均匀性下降,另外,悬浮体的粘度较大,很难控制直径较小的纤维;Williams等用切割法制备了压电纤维,由于该法是先制备压电陶瓷,再将其切割成纤维,纤维的大小与机械加工先进程度有关,但目前加工纤维横断面尺寸要达到100μm以下有一定难度;Brei等提出采用模板浸渍法制备碳纤维,该法制备的纤维具有一定的强度,纤维直径较细,但纤维极不平直,变形量很大;江苏大学用溶胶-粉末共混挤压法制备了直径为200-400μm的PZT纤维,此法制备的纤维密度较高,但纤维的粗细受模具的限制,要制备直径为100μm以下的平直纤维是极为困难的。
目前压电纤维阵列的获得基本上都是在制备压电纤维的基础上通过排列法得到,这种方法对于粗纤维构成的阵列有效,但对微细纤维,特别是直径小于几百微米的纤维,由于在操作的过程中很容易引起纤维的破损及阵列的混乱,因此采用排列法来得到阵列就显得极为不利。
本发明的目的在于提供一种所得纤维具有单一钙钛矿相结构,平直且致密度高,直径为5~100μm,整齐有序,具有高的压电性能,能用于传感/驱动器件中1-3压电纤维复合材料的PZT压电纤维阵列的制备方法。
一种微细平直PZT压电纤维阵列的制备方法,其特征在于:用塑料毛细管作为反应模板,首先制备PZT溶胶,然后加入PZT纳米粉末,混合均匀形成悬浮液,将塑料毛细管剪成适当的长度置于两端开口并能在PZT烧结温度范围内使用的容器中,用胶或石腊填充毛细管间的空隙及容器与塑料毛细管间的空隙并固化成需要的阵列形状,将装有塑料毛细管的容器浸入所述悬浮液中,待充分吸附后,然后将其余悬浮液从容器的一端倒入,并在另一端抽滤,以使含有纳米PZT粉末的悬浮液通过抽力进入塑料毛细管中,一直至毛细管内充满悬浮液;将装有塑料毛细管的容器干燥至无多余液体成份,取出重复多次浸渍、抽滤、干燥,将上述干燥后的装有塑料毛细管的容器进行模板脱除与晶化热处理,得到PZT压电纤维阵列结构。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:PZT溶胶制备方法如下:将醋酸铅、硝酸锆、钛酸四丁酯在溶剂和稳定剂中混合均匀后,加入水和醋酸,在80℃低温加热和超声振荡条件下使混合物混合反应,并在磁力搅拌器上搅拌均匀后获得所述的溶胶。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:溶胶-粉末混合体系的制备方法如下:将PZT溶胶和纳米PZT粉末混合,加入PEG作为分散剂,在80℃低温下加热均匀搅拌,并超声分散使得混合物与溶胶充分混合均匀。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:溶剂为乙二醇单甲醚,稳定剂为乙酰丙酮。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述PZT溶胶和纳米PZT粉末的重量比例为1:0.05~1:0.5;PZT溶胶中包含醋酸铅、硝酸锆、钛酸四丁酯、水和醋酸,PZT溶胶的浓度为0.2~1.0mol/l,其中醋酸铅、硝酸锆、钛酸四丁酯的物质的量的比例为100:(50~60):(40~48),水与醋酸的重量比例为1:0.5~1:2。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述醋酸铅、硝酸锆、钛酸四丁酯的物质的量的比例为100:56:44。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述水与醋酸的重量比例为1:1。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述溶胶的浓度0.35Mol/l。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述PZT溶胶和PZT粉末的重量比例为1:0.1。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述纳米PZT粉末与PEG重量比为:1:0.001~1:0.008。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述纳米PZT粉末与PEG重量比为:1:0.005。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述模板脱除与晶化热处理的过程为:室温~200℃,升温速率1℃/min,200℃保温1h;
200~600℃,升温速率2℃/min,600℃保温1~2h; 600℃~950℃,升温速率3.5℃/ min,保温30 分钟。
所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述容器为石英管。
与现有的制备方法相比,本发明的突出优点:本方法可以精确控制纤维的直径和长度,能制备出直径仅在几个微米至几百微米,长度为0.5cm~3cm,平直而致密度高的PZT微细压电纤维,该PZT压电纤维具有单一钙钛矿相结构,表面光滑,具有高的压电性能;其次,本方法制备出的压电纤维不需手工排列即可直接形成各种需要的阵列结构,纤维排列整齐有序且破损少。
图1为PZT压电纤维在750℃和950℃二种温度下烧结的X射线衍射谱图。图1中横坐标为衍射角,纵坐标为衍射强度。图1显示950℃烧结后纤维即具有单一的钙钛矿相;
图2为PZT压电纤维经950℃烧结后的扫描电镜图,图中纤维形貌显示纤维较为致密,无气孔;
图3为PZT压电纤维阵列在950℃烧结的扫描电镜图,图中纤维排列整齐有序,破损少。
本发明设计的一种PZT压电纤维及其阵列结构,其特征在于用塑料毛细管作为模板,采用溶胶-PZT纳米粉末共混吸附与反应的方法来制备微细平直的PZT陶瓷纤维阵列。
其中溶胶和纳米PZT粉末的比例为1:0.05~1:0.5;溶胶中包含醋酸铅、硝酸锆、钛酸四丁酯、水、醋酸,溶胶的浓度为0.2~1.0mol/l,其中醋酸铅、硝酸锆、钛酸四丁酯的比例为100:(50~60):(40~48),水与醋酸的比例为1:0.5~1:2。
本发明所述PZT压电纤维的制备方法是按下列工艺进行:
1.PZT溶胶制备:将所述比例的醋酸铅、硝酸锆、钛酸四丁酯在的溶剂和稳定剂中处理后与上述比例的水和醋酸进行混合,在80℃低温加热和超声振荡条件下使混合物混合均匀,并在磁力搅拌器上搅拌均匀并完全产生水解反应后获得所述的溶胶;
2.溶胶-粉末混合体系的制备:将溶胶和纳米PZT粉末按上述所述比例混合,加入PEG作为分散剂,在80℃低温下加热均匀搅拌,并超声分散使得混合物与溶胶充分混合均匀;
3.PZT压电纤维的制备:将塑料毛细管剪成适当的长度,用胶或石腊填充毛细管间的空隙并固化成一定的阵列形状,置于石英管中,石英管与塑料毛细管间的空隙部分用胶或石腊等封住。先将装有塑料毛细管的石英管浸入所得悬浮液中,待充分吸附后,然后将所得悬浮液从石英管的上部缓缓倒入,并在下方抽滤,以使纳米PZT粉末通过抽力进入塑料毛细管中,一直至毛细管内充满粉末颗粒,将石英管与塑料毛细管置于烘箱内60℃干燥至无多余液体成份,取出重复多次浸渍、抽滤、干燥数次;
4.PZT压电纤维的热处理:将干燥后的石英管连同含纤维的塑料毛细管置于热处理炉内进行模板脱除与晶化热处理,得到PZT压电纤维阵列结构。
本发明PZT压电纤维及其阵列结构的制造方法所述的溶胶中溶剂为乙二醇单甲醚,稳定剂为乙酰丙酮。
本发明新型PZT压电纤维阵列的制造方法所述醋酸铅、硝酸锆、钛酸四丁酯的比例为100:(50~60):(40~48),最佳比例为100:56:44;溶胶粉末体系中,粉末均为纳米PZT粉,
如纳米PZT5,其中Zr:Ti=56:44。
本发明PZT压电纤维的制造方法所述水和醋酸比为1:0.5~1:2,理想比例为
1:1。若比例过大,则由于水的含量过高,溶胶的水解速度较快,会形成凝胶失去流动性;反之,比例过小,醋酸的含量过高,虽然有利于抑制水解的进行,但是在干燥和烧成的过程中,醋酸会挥发,扩大了纤维的收缩,同时还留下了大量的气孔,降低了纤维的致密度和强度,因此要求水和醋酸的比例在所述的范围内。
本发明PZT压电纤维的制造方法所述溶胶的浓度为0.2~1.0mol/l,理想浓度为0.35Mol/l。浓度过高,溶胶的粘度过大PZT纳米粉体不易分散;浓度过低,制备的纤维致密度受影响,因此要求溶胶浓度在一定的范围内。
本发明PZT压电纤维的制造方法所述溶胶和PZT粉末比为1:0.05~1:0.5,理想比例为1:0.1,当比例过高时,固相含量较低,粘度过低,形成纤维易变形,反之比例过低,溶胶粉末体系流动性差,易堵塞模板,因此,要求溶胶和PZT粉末的比例在所述范围内。
本发明的纳米PZT粉末与PEG重量比为:1:0.001~1:0.008,理想比例为1:0.005,当比例过大时,易形成胶束对纳米粉末在溶胶中的分散不利,当比例过少,不易达到良好分散粉末的目的,因此,要求粉末与PEG的比例在所述范围内。
本发明PZT压电纤维的制造方法所述热处理过程为:1.
室温~200℃,升温速率1℃/min,200℃保温1h,主要是纤维前驱体中水分及部分有机物的挥发;2.
200~600℃,升温速率2℃/min,600℃保温1~2h,主要为有机物的挥发和分解以及PZT纤维的晶化;3. 600℃~950℃,升温速率3.5℃/
min,主要为晶粒长大,纤维致密化和气孔的排出,保温30 分钟。
以下给出本发明的几个具体实施例:
实施例1:
按摩尔比为100:56:44称取醋酸铅、硝酸锆、钛酸四丁酯四种原料,用乙二醇单甲醚均匀溶解混合,加入1:1的水和醋酸,在磁力搅拌作用下调整溶液浓度为0.3mol/l,获得溶胶,取溶胶10份,按溶胶:PZT粉末重量比为1:0.1称取1份的PZT纳米粉末,再加入PEG1000,加入量为PZT纳米粉末的0.5%,在磁力搅拌作用下分散半小时后置于超声分散仪中分散2小时,制备溶胶粉末体系,将内径为0.25mm的薄壁塑料毛细管剪成2cm长度,取50根排列成圆截面阵列形状,用石腊填充毛细管间的空隙置于内径为1cm的石英管中,室温固化30分钟,再用少量石腊封住石英管与塑料毛细管间的空隙,将装有塑料毛细管的石英管浸入上述溶胶粉末混合所得的悬浮液中。待充分吸附后,将上述悬浮液从石英管的上部缓缓倒入,并在下方抽滤,以使纳米PZT粉末通过抽力进入塑料毛细管中,一直至毛细管内充满粉末颗粒。将石英管与塑料毛细管置于烘箱内60℃干燥至无多余液体成份,取出重复三次浸渍、抽滤、干燥,将上述石英管连同含纤维的塑料毛细管置于热处理炉内煅烧至950℃进行模板与石腊的脱除、烧结,得到平均直径约为50μm,长度约为0.8cm的PZT压电纤维及其呈圆截面阵列整齐排列的结构。
按摩尔比为100:56:44称取醋酸铅、硝酸锆、钛酸四丁酯四种原料,用乙二醇单甲醚均匀溶解混合,加入1:1的水和醋酸,在磁力搅拌作用下调整溶液浓度为0.3mol/l,获得溶胶,取溶胶10份,按溶胶:PZT粉末重量比为1:0.1称取1份的PZT纳米粉末,再加入PEG1000,加入量为PZT纳米粉末的0.5%,在磁力搅拌作用下分散半小时后置于超声分散仪中分散2小时,制备溶胶粉末体系,将内径为0.25mm的薄壁塑料毛细管剪成2cm长度,取50根排列成圆截面阵列形状,用石腊填充毛细管间的空隙置于内径为1cm的石英管中,室温固化30分钟,再用少量石腊封住石英管与塑料毛细管间的空隙,将装有塑料毛细管的石英管浸入上述溶胶粉末混合所得的悬浮液中。待充分吸附后,将上述悬浮液从石英管的上部缓缓倒入,并在下方抽滤,以使纳米PZT粉末通过抽力进入塑料毛细管中,一直至毛细管内充满粉末颗粒。将石英管与塑料毛细管置于烘箱内60℃干燥至无多余液体成份,取出重复三次浸渍、抽滤、干燥,将上述石英管连同含纤维的塑料毛细管置于热处理炉内煅烧至950℃进行模板与石腊的脱除、烧结,得到平均直径约为50μm,长度约为0.8cm的PZT压电纤维及其呈圆截面阵列整齐排列的结构。
实施例2:
按摩尔比为100:56:44称取醋酸铅、硝酸锆、钛酸四丁酯四种原料,用乙二醇单甲醚均匀溶解混合,加入1:1的水和醋酸,在磁力搅拌作用下调整溶液浓度为0.5mol/l,获得溶胶,取溶胶100份,按溶胶:PZT粉末重量比为1:0.06称取6份的PZT纳米粉末,再加入PEG400和PEG2000,加入量为PZT纳米粉末的0.6%,在磁力搅拌作用下分散半小时后置于超声分散仪中分散2小时,制备溶胶粉末体系,将内径为0.3mm的薄壁塑料毛细管剪成4cm长度,取100根排列成圆截面阵列形状,用501万能胶填充毛细管间的空隙置于内径为2cm的石英管中,室温固化6小时,再用少量501万能胶封住石英管与塑料毛细管间的空隙,将装有塑料毛细管的石英管浸入上述溶胶粉末混合所得的悬浮液中,待充分吸附后,将上述悬浮液从石英管的上部缓缓倒入,并在下方抽滤,以使纳米PZT粉末通过抽力进入塑料毛细管中,一直至毛细管内充满粉末颗粒,将石英管与塑料毛细管置于烘箱内60℃干燥至无多余液体成份,取出重复多次浸渍、抽滤、干燥数次,将上述石英管连同含纤维的塑料毛细管置于热处理炉内煅烧至1000℃进行模板与胶的脱除、烧结,得到平均直径约为80μm,长度为1.5cm左右的PZT压电纤维及其呈圆截面阵列整齐排列的结构。
按摩尔比为100:56:44称取醋酸铅、硝酸锆、钛酸四丁酯四种原料,用乙二醇单甲醚均匀溶解混合,加入1:1的水和醋酸,在磁力搅拌作用下调整溶液浓度为0.5mol/l,获得溶胶,取溶胶100份,按溶胶:PZT粉末重量比为1:0.06称取6份的PZT纳米粉末,再加入PEG400和PEG2000,加入量为PZT纳米粉末的0.6%,在磁力搅拌作用下分散半小时后置于超声分散仪中分散2小时,制备溶胶粉末体系,将内径为0.3mm的薄壁塑料毛细管剪成4cm长度,取100根排列成圆截面阵列形状,用501万能胶填充毛细管间的空隙置于内径为2cm的石英管中,室温固化6小时,再用少量501万能胶封住石英管与塑料毛细管间的空隙,将装有塑料毛细管的石英管浸入上述溶胶粉末混合所得的悬浮液中,待充分吸附后,将上述悬浮液从石英管的上部缓缓倒入,并在下方抽滤,以使纳米PZT粉末通过抽力进入塑料毛细管中,一直至毛细管内充满粉末颗粒,将石英管与塑料毛细管置于烘箱内60℃干燥至无多余液体成份,取出重复多次浸渍、抽滤、干燥数次,将上述石英管连同含纤维的塑料毛细管置于热处理炉内煅烧至1000℃进行模板与胶的脱除、烧结,得到平均直径约为80μm,长度为1.5cm左右的PZT压电纤维及其呈圆截面阵列整齐排列的结构。
实施例3:
按摩尔比为100:56:44称取醋酸铅、硝酸锆、钛酸四丁酯四种原料,用乙二醇单甲醚均匀溶解混合,加入1:1的水和醋酸,在磁力搅拌作用下调整溶液浓度为0.35mol/l,获得溶胶,取溶胶10份,按溶胶:PZT粉末重量比为1:0.4称取4份的PZT纳米粉末,再加入PEG1000,其重量为PZT纳米粉末的0.5%,在磁力搅拌作用下分散半小时后置于超声分散仪中分散2小时,制备溶胶粉末体系,将内径为0.1mm的薄壁塑料毛细管剪成2cm长度,取49根排列成7×7根的方形阵列形状,用501万能胶填充毛细管间的空隙置于内径为4cm的石英管中,室温固化6小时,再用少量501万能胶封住石英管与塑料毛细管间的空隙,将装有塑料毛细管的石英管浸入上述溶胶粉末混合所得的悬浮液中,待充分吸附后,将上述悬浮液从石英管的上部缓缓倒入,并在下方抽滤,以使纳米PZT粉末通过抽力进入塑料毛细管中,一直至毛细管内充满粉末颗粒,将石英管与塑料毛细管置于烘箱内60℃干燥至无多余液体成份,取出重复多次浸渍、抽滤、干燥数次,将上述石英管连同含纤维的塑料毛细管置于热处理炉内煅烧至950℃进行模板与胶的脱除、烧结,得到平均直径约为30μm,长度为0.8cm左右的7×7根PZT压电纤维方形阵列结构。
按摩尔比为100:56:44称取醋酸铅、硝酸锆、钛酸四丁酯四种原料,用乙二醇单甲醚均匀溶解混合,加入1:1的水和醋酸,在磁力搅拌作用下调整溶液浓度为0.35mol/l,获得溶胶,取溶胶10份,按溶胶:PZT粉末重量比为1:0.4称取4份的PZT纳米粉末,再加入PEG1000,其重量为PZT纳米粉末的0.5%,在磁力搅拌作用下分散半小时后置于超声分散仪中分散2小时,制备溶胶粉末体系,将内径为0.1mm的薄壁塑料毛细管剪成2cm长度,取49根排列成7×7根的方形阵列形状,用501万能胶填充毛细管间的空隙置于内径为4cm的石英管中,室温固化6小时,再用少量501万能胶封住石英管与塑料毛细管间的空隙,将装有塑料毛细管的石英管浸入上述溶胶粉末混合所得的悬浮液中,待充分吸附后,将上述悬浮液从石英管的上部缓缓倒入,并在下方抽滤,以使纳米PZT粉末通过抽力进入塑料毛细管中,一直至毛细管内充满粉末颗粒,将石英管与塑料毛细管置于烘箱内60℃干燥至无多余液体成份,取出重复多次浸渍、抽滤、干燥数次,将上述石英管连同含纤维的塑料毛细管置于热处理炉内煅烧至950℃进行模板与胶的脱除、烧结,得到平均直径约为30μm,长度为0.8cm左右的7×7根PZT压电纤维方形阵列结构。
Claims (10)
- 一种微细平直PZT压电纤维阵列的制备方法,其特征在于:用塑料毛细管作为反应模板,首先制备PZT溶胶,然后加入PZT纳米粉末,混合均匀形成悬浮液,将塑料毛细管剪成适当的长度置于两端开口并能在PZT烧结温度范围内使用的容器中,用胶或石腊填充毛细管间的空隙及容器与塑料毛细管间的空隙并固化成需要的阵列形状,将装有塑料毛细管的容器浸入所述悬浮液中,待充分吸附后,然后将其余悬浮液从容器的一端倒入,并在另一端抽滤,以使含有纳米PZT粉末的悬浮液通过抽力进入塑料毛细管中,一直至毛细管内充满悬浮液;将装有塑料毛细管的容器干燥至无多余液体成份,取出重复多次浸渍、抽滤、干燥,将上述干燥后的装有塑料毛细管的容器进行模板脱除与晶化热处理,得到PZT压电纤维阵列结构。
- 如权利要求1所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:PZT溶胶制备方法如下:将醋酸铅、硝酸锆、钛酸四丁酯在溶剂和稳定剂中混合均匀后,加入水和醋酸,在80℃低温加热和超声振荡条件下使混合物混合反应,并在磁力搅拌器上搅拌均匀后获得所述的溶胶。
- 如权利要求1所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:溶胶-粉末混合体系的制备方法如下:将PZT溶胶和纳米PZT粉末混合,加入PEG作为分散剂,在80℃低温下加热均匀搅拌,并超声分散使得混合物与溶胶充分混合均匀。
- 如权利要求2所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:溶剂为乙二醇单甲醚,稳定剂为乙酰丙酮。
- 如权利要求1所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述PZT溶胶和PZT纳米粉末的重量比例为1:0.05~1:0.5;PZT溶胶中包含醋酸铅、硝酸锆、钛酸四丁酯、水和醋酸,PZT溶胶的浓度为0.2~1.0mol/l,其中醋酸铅、硝酸锆、钛酸四丁酯的物质的量的比例为100:(50~60):(40~48),水与醋酸的重量比例为1:0.5~1:2。
- 如权利要求5所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述醋酸铅、硝酸锆、钛酸四丁酯的物质的量的比例为100:56:44,所述水与醋酸的重量比例为1:1,所述溶胶的浓度0.35Mol/l,所述PZT溶胶和PZT粉末的重量比例为1:0.1。
- 如权利要求3所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述纳米PZT粉末与PEG重量比为:1:0.001~1:0.008。
- 如权利要求7所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述纳米PZT粉末与PEG重量比为:1:0.005。
- 如权利要求1所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述模板脱除与晶化热处理的过程为:室温~200℃,升温速率1℃/min,200℃保温1h; 200~600℃,升温速率2℃/min,600℃保温1~2h; 600℃~950℃,升温速率3.5℃/ min,保温30 分钟。
- 如权利要求1所述的一种微细平直PZT压电纤维阵列的制备方法,其特征在于:所述容器为石英管。
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CN103898632B (zh) * | 2012-12-28 | 2016-03-02 | 中国科学院声学研究所 | 一种致密压电陶瓷纤维的制备方法及致密压电陶瓷纤维 |
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CN102051710A (zh) | 2011-05-11 |
US20140157558A1 (en) | 2014-06-12 |
CN102051710B (zh) | 2012-11-07 |
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