反應(yīng)器內(nèi)流場(chǎng)分布對(duì)球形氫氧化鎳生長(zhǎng)結(jié)晶的影響

唐俊杰　劉　燕　田　磊　王東興　張廷安

(東北大學(xué)多金屬共生礦生態(tài)化冶金教育部重點(diǎn)實(shí)驗(yàn)室，沈陽(yáng)110819)

反應(yīng)器內(nèi)流場(chǎng)分布對(duì)球形氫氧化鎳生長(zhǎng)結(jié)晶的影響

唐俊杰劉燕＊田磊王東興張廷安

(東北大學(xué)多金屬共生礦生態(tài)化冶金教育部重點(diǎn)實(shí)驗(yàn)室，沈陽(yáng)110819)

在相同停留時(shí)間、不同攪拌槳線速度條件下，利用化學(xué)沉淀法制備球形氫氧化鎳樣品并運(yùn)用SEM技術(shù)考察制得樣品的形貌。研究表明：在相同的停留時(shí)間和化學(xué)條件下，隨著攪拌槳線速度的提高樣品的微觀形貌由無(wú)定型狀晶體變?yōu)榇箢w粒類球狀晶體再變?yōu)檩^規(guī)則的球狀晶體。利用PIV物理模擬技術(shù)模擬反應(yīng)器內(nèi)流場(chǎng)分布情況并結(jié)合XRD表征結(jié)果分析得出：在相同的停留時(shí)間和化學(xué)條件下，反應(yīng)器內(nèi)流場(chǎng)分布越均勻、速度矢量越大氫氧化鎳晶體的生長(zhǎng)越完整，結(jié)晶性、球形度和相對(duì)結(jié)晶度越高，并從流場(chǎng)分布的角度描述了球形氫氧化鎳生長(zhǎng)結(jié)晶的過(guò)程。

球形氫氧化鎳；流場(chǎng)分布；相對(duì)結(jié)晶度；生長(zhǎng)結(jié)晶

0　Introduction

Spherical Ni(OH)2is one of themost important battery materials which has been widely applied in communication,spaceflight,digital and so on.Some problemssuch as large structure differences in different batches always appear in themanufacture of spherical Ni(OH)2products.Peng etal.studied the influence of turbine blade and propelled paddle on the crystallization of spherical Ni(OH)2,and they concluded that inthe same energy consumption,the use of turbine blade can get more uniform growth product[1-3].Shen etal.explained the growth processofspherical Ni(OH)2crystal by a growth model[4-5].Al-Hajry etal.studied the growth of flower-shaped Ni(OH)2crystal,and they suggested that the flower-shaped crystal is consisted of thin nanosheetswhich are connected each other and they form network-like morphologies[6]. Hironori etal.studied the crystalgrowth ofβ-Ni(OH)2in hydrothermal synthesis process,and the changes of the number and size of crystalswith the hydrothermal reaction period were quantitatively analyzed by using the TEM images.Moreover,the crystallization was controlled by the size limitof the nanochannels[7].

The stirring plays a key role in the control of the crystallization process.Sancho et al.studied the characteristics of themixing layer flow in a cylindrical reactor by PIV and PLIF technology,and they concluded that the rapid irreversible reaction particles with smaller displacement in the flow field cannot significantly increase the reaction rate,but it can improve the mixing degree of the reactants[8-13]. Fukushima et al.used the PIV and PTV technique to investigate the particle dispersion in different regions of the reactor during the mixing process,and get relevant experience for controlling the crystallization which is related to concentration[14-15].

The controlof the spherical Ni(OH)2crystallization has great relationship to the concentration of the material in the reactor and the degree of mixing.To investigate the process of the spherical Ni(OH)2crystallization,scientistsmainly take the temperature, pH value(ammonia content),reactant supersaturation, mixing intensity and paddle type and other aspects into consideration at present.However,the influence of the field distribution inside reactor on the crystal growth of spherical Ni(OH)2was rarely studied. Therefore,in this study the spherical Ni(OH)2was synthesized by chemical precipitation method under different linear velocities of the stirring blades.The morphologies and relative crystallinity of the spherical Ni(OH)2were characterized by SEM and XRD.Then the flow field distribution in the reactor under different linear velocities of the stirring blades was simulated by PIV physicalmodel technology.The relationship between flow flied distribution and Ni (OH)2crystallization was concluded from the experimental and simulation results.This study provides a theoretical basis and experience,both for reducing the structure difference in Ni(OH)2industrial productsand the structure design of industrial reactor.

1　Experimental

1.1Reactor design

According to the investigation on the spherical Ni(OH)2industrial production reactor,and the understanding of the hydrodynamic conditions such as the velocity field,concentration field,temperature field and residence time distribution in the reactor and the transfer behavior,a 200 L organic glassmodel reactor was designed by NL=Ns(DS/DL)Xsimilar geometry principle(for this system themagnification factor X= 1～3/4,because the industrial chemical precipitation method for the preparation ofspherical Ni(OH)2system is solid-liquid suspension system).

1.2Preparation of spherical Ni(OH)2

According to the industrial process of spherical Ni(OH)2preparation,the chemicalprecipitationmethod was applied to the preparation of spherical Ni(OH)2in this experiment.The reaction temperature of the system is controlled at 50～57℃,and the pH value is controlled at 11～11.7.A certain concentration of nickel sulfate solution,ammonia,sodium hydroxide solution in a certain proportion was filled to the bottom of the reactor.Under the same residence time, the sample is prepared under the stirring paddle line speed of 1,3,5 and 7 m·s-1,and then the sample is filtered and washed to dry,waiting formeasurement. 1.3 SEM experiments

When the impeller line speed is1m·s-1and 3m· s-1,the Ni(OH)2particles are irregular shape crystals with different size,and the surface of the crystal is formed by the stacking of lamella micro-crystals with attached particles,such as Fig.1～2.When the impeller line speed is 5 m·s-1,Ni(OH)2particles formed many near spherical crystals,the surface ofwhich is formedby the accumulation of many well-defined lamellar micro-crystals,such as Fig.3.When the impeller line speed is 7 m·s-1,Nickel hydroxide particles formed spherical crystals with similar morphology and size, and the surface of these crystals is composed of the accumulation of many micro-crystals with clear stripes,such as Fig.4.

Fig.1　SEM image of Ni(OH)2particles(impeller line speed 1m·s-1)

Fig.2　SEM image of Ni(OH)2particles(impeller line speed 3m·s-1)

Fig.3　SEM image of Ni(OH)2particles(impeller line speed 5 m·s-1)

Fig.4　SEM image of Ni(OH)2particles(impeller line speed 7 m·s-1)

2　Results and discussion

2.1PIV analysis

The crystallization porcess of spherical Ni(OH)2crystal can be divided into nucleation and crystal growth.Therefore,if the nucleus formation speed is fastand the crystalgrowth rate is slow,the nucleuswill gradually form amorphous Ni(OH)2crystal.Ammonia is commonly used as a compounding agent which reacts with nickel ions to lower the concentration of reactants in industry,and the nucleation and growth rate of nickel hydroxide crystal can reach a reasonable reaction rates to form spherical nickel hydroxide(Equation 1).The flow velocity vector and distribution in the reactor determine the mixed uniform rate and state of reagentand ingredient,which also indirectly affects the crystallization,spheri-city, growth uniformity of spherical Ni(OH)2and other important products indicators.

When the impeller line speed is 1 m·s-1,the cloud image of the absolute velocity vector in the reactor is shown in Fig.5.It can be seen from the graph that in both sides and the bottom area of the mixing paddle the velocity vector distribution is larger,which is the relatively high velocity zone of the liquid flow,and the direction of the liquid flow is from the bottom to the top.Three stirring circulation appeared in the reactor A,B and C areas,and the velocity vector in A,B and C areas is lower than other areas.When the impeller line speed is 3 m·s-1, the cloud image of the absolute velocity vector in thereactor is shown in Fig.6.It can be seen from the graph that in both sides and the bottom area of the mixing paddle the velocity vector distribution is larger than before,but in the three circulation flow areas the velocity vector distributions show no significantly change.The area such as A,Band C is named as stirring dead zone.In the above two kinds of flow field distribution,because the velocity vector distribution in the reactor is low,the range of the stirring dead zone increases,which leads to the slowlymixing rate of the reaction materials and cooperation agent ammonia, and to low mixed degree of uniformity,consequently the Ni(OH)2crystal nucleation rate is fast but crystal growth rate is slow,forming amorphous crystalline with varying sizes(Fig.1～2).

Fig.5　Cloud image of the system(absolute velocity vector 1m·s-1)

Fig.6　Cloud image of the system(absolute velocity vector 3m·s-1)

As shown in Fig.7,when the impeller line speed increases to 5 m·s-1,the fluid flow direction is from bottom to up,which is similar to that when the impeller line speed is 1 and 3 m·s-1.The relatively high liquid flow velocity region at both sides of the shaft and the bottom of the stirring paddle expands and the velocity vector increases.At the A,B and C areas the stirring circulation velocity reactor show little variation with the increase of the stirring paddle line speed,but the mixing circulation range is reduced obviously.Due to increasing the flow velocity vector in the reactor and decreasing the stirring dead zone range,the mixed uniform extent of reactor reactant and cooperation agent raise,same to mixing rate.Ni(OH)2particlesget togetherand grow intomany large spherical crystals(Fig.7).Since in the reactor flow velocity vector and distribution uniform has not achieved ideal value,the aggregation growth of the spherical crystals does not aggregate,and not collide with each other and break to enter into the secondary crystallization stage,therefore does not form good sphericity of spherical nickel hydroxide crystal.

Fig.7　Cloud image of the system(absolute velocity vector 5m·s-1)

Fig.8　Cloud image of the system(absolute velocity vector 7m·s-1)

As shown in Fig.8,when the impeller line speed increases to 7 m·s-1,the relatively high liquid flow velocity region at both sides of the shaft and the bottom of the stirring paddle expands and the velocity vector continues to increase,and at the A,B and Careas the stirring circulation velocity reactor still doesn't increase obviously,but the mixing circulation range gets smaller.Due to the change of the fluid flow distribution in the reactor,themixed uniform extent of reactor reactant and mixing rate continue to rise.The nucleation rate and growth rate of the Ni(OH)2crystals reached a relative equilibrium,and under high speed flow field larger crystals formed many crystalline, sphericity,homogeneous volume spherical Ni(OH)2crystal by collision crushing secondary crystallization (Fig.8).

The agglomeration effect of particles plays a key role in the entire process of the crystal growth of spherical Ni(OH)2[1].When the impeller line speed is 1 or 3 m·s-1,the flow velocity vector is low and flow field distribution is not uniform in the reactor,which leads to the results that the mixed uniformity of the reactant is low,therefore,agglomeration rateofNi(OH)2particles is low.Somostof the nickel ion and ammonia ions does not occur the complexation reaction,but formed the nickel hydroxide precipitation.When the stirring paddle line speed increases to 5 m·s-1,the flow velocity vector becomes larger in the reactor,and the stirring circulation dead range is narrow,the flow field distribution is more uniform,so the mixed uniformity of the complexing agent and reactant improved,and more nickel ions complexation reacts with ammonia ions,which lead to slow rate of crystal nucleation,and to increasing crystal aggregation rate at the same time,particles agglomerate into many complete crystallization of large crystalswith the same residence time.It can be concluded that as increasing flow velocity vector and uniform distribution in the reactor,the nickel hydroxide particles aggregation rate and sphericity also increases.When the stirring paddle line speed is 7 m·s-1,the distribution of flow field in the reactor and uniformity of velocity vector reach an ideal value,and the mixing of the complexing agent and the reactant reach an ideal state,and appropriate complexing reaction balance the crystal nucleation and crystal growth rate.At high speed flow field some large crystal aggregates collide and break to occur the secondary crystallization,and spherical nickel hydroxide crystals with uniform size and high degree form.It is shown that in the reactor only flow velocity vector reach a fixed value,large particles of Ni(OH)2crystal can lead to aggregation burst into the secondary crystallization,therefore,the crystal growth of uniformity is improved.

2.2XRD analysis

The XRD instrument used in this experiment is D8 Advance X XBruker ray analyzer produced by German Bruker company.Light tube type is Cu target, ceramic X light tube.λ=0.154 06 nm,scan range is 10°～90°,the scanning speed is2°·min-1.XRD patterns of the samples which were prepared at different mixing speed is shown in Fig.9.

Fig.9　XRD patterns of the samples at different mixing speed

From Fig.9it can be found that themain peak is nickel hydroxide,and other crystal items were not observed.When the line speed is 7 m·s-1,the diffraction peak in the XRD spectrum is highest,the half width of the peak is minimum,and the relative crystallinity of the best.If the best relative degree of crystallinity samples prepared at 7 m·s-1is treated as relative crystallinity of 100%,according to amorphization formula A=(1-U0Ix/UxI0)×100%,the calculation of amorphous salinity of each sample is plotted in a linear graph,as shown in Fig.10.Moreover,the relationship between line speed V(m·s-1)and amorphization:A=1-0.479 4e0.1041Vcan be obtained according to Fig.10.

Fig.10　Relationship between line speed and amorphization

2.3Relative particle size difference analysis

The particle size distribution instrument used in this experiment is MASTERSIZER 2000 produced by Malvern Instruments Ltd.The particle size distribution of the sample at different mixing speed is given in Table1.From Table1it can be found that when the line speed is7m·s-1,the relative particle size difference F=d0.9-d0.5isminimum.Moreover,according Table1can be obtained Fig.11.From Fig.11can lead to the relationship between relative particle size difference and line speed:F(0.5～0.9)=-15.59ln V+41.172.

Fig.11　Relative particle size difference at different mixing speed

Table1　Particle size distribution and size difference

2.4CV analysis

The electrochemical activity is the basic indicator of Ni(OH)2.The Ni(OH)2samples prepared of different stirring line speeds are compressed with carbon black and adhesive in proportionas7∶2∶1 intosheetselectrode. CV Scan is tested at the speed of 10 mA·s-1in the range of 0～0.6 V,while the Hg/HgO is selected as the contrast electrode.The cycle voltammogram is shown in Fig.12.When the line speed is 7 m·s-1,the area of electrochemical activity and peak current reach the maximum,which show the best electrochemical performance.

Fig.12　CV curves of Ni(OH)2samples at differentmixing speed

3　Conclusions

(1)In the same retention time and chemical condition,the growth integrity,uniform,crystallization, sphericity and the particles aggregation rate of spherical Ni(OH)2crystals is proportional to the distribution range of the flow velocity vector and uniformity in the reactor.

(2)In the same retention time and chemical condition,large particles of Ni(OH)2crystals can lead to aggregation burst and the secondary crystallization to form Ni(OH)2crystals with uniform size when flow velocity vector in the reactor reaches a fixed value. Moreover,from the particle size distribution atdifferent line speed the relationship between relative particle sizedifference F(μm)and line speed V(m·s-1); F(0.5～0.9)=-15.59ln V+41.172 can be obtained.

(3)In the same retention time and chemical condition,from the XRD characterization it can be obtained thatthe relativecrystallinityofNi(OH)2crystals is proportional to the velocity distribution of the flow field size and uniformity in the reactor,and nickel hydroxide is proportional to the distribution range of the flow velocity vector and uniformity in the reactor. But the velocity distribution of the flow field size and uniformity in the reactor does not affect the crystallization of other crystal items.Moreover,the relationship between line speed V(m·s-1)and amorphization:A= 1-0.479 4e0.1041Vcanbeobtained according XRD.

(4)The electrochemical activity of Ni(OH)2is proportional to the uniformity of flow distribution and velocity vector in the container when the residence time has no change.Moreover,it is confirmed that the electrochemical activity is proportional to the relative crystallinity and growth integrality of the spherical Ni(OH)2.

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Influence of Flow Field Distribution on the Crystallization of Spherical Nickel Hydroxide in Reactor

TANG Jun-Jie LIU Yan＊TIAN Lei WANG Dong-Xing ZHANG Ting-An
(Key Laboratory for Ecological Utilization of Multimetallic Mineral,Ministry of Education, Northeastern University,Shenyang 110819,China)

The spherical nickel hydroxide was synthesized by chemical precipitation method under the conditions of the same stay time but different linear velocities of the stirring blades.Then themorphologies of the spherical Ni(OH)2were characterized by SEM.In the same retention time and chemical condition,itwas found thatwith increasing the linear velocity,themorphology of the spherical Ni(OH)2changed from amorphous crystals to large near spherical particles at first,and then to regular spherical crystals finally.The flow field distribution in the reactor was simulated by PIV physicalmodel technology.And XRD results show that in the same retention time and chemical condition,more uniform flow field distribution in the reactor and higher velocity vector can lead to more complete Ni(OH)2crystals,higher relative crystallinity and higher degree of sphericity.Moreover,the crystallization process of spherical Ni(OH)2was described from the flow field viewpoint.

spherical Ni(OH)2;flow field distribution;relative crystallinity;crystallization

O614.81+3

A

1001-4861(2016)07-1127-08

10.11862/CJIC.2016.156

2016-01-25。收修改稿日期：2016-05-29。

國(guó)家國(guó)家自然科學(xué)基金云南聯(lián)合重點(diǎn)基金(No.U1402271，U1202274)資助項(xiàng)目。

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