JP2004301632A - Powder strength determining method and grain size measuring device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technology for accurately determining strength of powder such as a granule by a quick and simple method. <P>SOLUTION: An ultrasonic wave is impressed on the powder of a strength determining object. Next, strength of the powder is determined by comparing information (a) on the grain size of the powder impressed with the ultrasonic wave with information (b) on the grain size of the powder held in advance. The information on the grain size includes various data such as the grain size distribution, the average particle size, a peak value of the grain size distribution, and a frequency of a particle having the prescribed grain size. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

【００３６】
表１に示すように、強度判定用超音波の出力が６０Ｗ、８０Ｗ、１００Ｗ、１５０Ｗと増加するにともない、頻度比が徐々に増加する。これは、強度判定用超音波の出力の増大にともない、微粉化が進行していることを示している。また、図４からは、当初の正規分布が崩れて、粒径が小さい粒子が増えていることがわかる。ここで、本実験例では、強度判定用超音波の印加条件が１００Ｗ×１ｍｉｎの場合の基準頻度比を０．３に設定しているものとする。この基準頻度比と、表１に示した強度判定用超音波の出力が１００Ｗの場合の頻度比を比較すると、この頻度比は基準頻度比より小さい。これにより、この粉体は所望の強度を有するものと判定することができる。
【００３７】
ここで、図５にＳＥＭ（走査型電子顕微鏡）観察像を示す。図５（ａ）は分散用超音波を印加した状態の粉体を観察した結果、図５（ｂ）は８０Ｗ×１ｍｉｎの強度判定用超音波を印加した後の粉体を観察した結果、図５（ｃ）は１５０Ｗ×１ｍｉｎの強度判定用超音波が施された後の粉体を観察した結果をそれぞれ示している。図５からも、超音波処理にともない、粉体としての顆粒が徐々に微粉化されていくこと、１５０Ｗ×１ｍｉｎという高い出力で強度判定用超音波が印加された場合には、顆粒のほとんどが一次粒子に粉砕されていることがわかる。
【００３８】
（実験例２）
実験例１で同様の条件で作製された平均粒径およびピーク径がいずれも４．６μｍである顆粒を、実験例１と同様の手順で粒度分布測定装置に投入した。この粉体の分散用超音波印加後の頻度比は実験例１と同様に０．１５５である。
【００３９】
次に、強度判定用超音波印加の条件を表２に示す３段階に設定し、各超音波処理後の顆粒の頻度比を求めた。その値を、それぞれの平均粒径とともに表２に併せて示す。また、表２には、強度判定用超音波印加前後の試料をＳＥＭ（走査型電子顕微鏡）で観察した結果を併せて示している。さらにまた、強度判定用超音波印加前後にともなう顆粒粒度分布の変化を、図６に示す。
【００４０】
【表２】

【００４１】
表２に示すように、実験例１の場合と同様に、強度判定用超音波の出力が６０Ｗ、８０Ｗ、１００Ｗと増加するにともない、頻度比が徐々に増加する。また、図６からは、当初の正規分布が崩れて、粒径が小さい粒子が増えていることがわかる。ここで、本実験例では、強度判定用超音波印加条件が８０Ｗ×５ｍｉｎの場合の基準頻度比を０．３に設定しているものとする。この基準頻度比と、表２に示した強度判定用超音波の出力が８０Ｗ×５ｍｉｎの場合の頻度比を比較すると、この頻度比は基準頻度比より小さい。これにより、この粉体は所望の強度を有するものと判定することができる。
【００４２】
（実験例３）
平均粒径１．１μｍの粉体を用いて、固形分５７．９ｗｔ％のスラリを作製した。このスラリにバインダとしてＰＶＡ（ポリビニルアルコール）を１ｗｔ％添加したものをスプレードライヤで造粒し顆粒化した。乾燥条件およびスラリ供給量を以下のように設定した。
【００４３】
得られた顆粒のうち０．１５ｇをサンプリングし、これを分散媒としてのメタノール１００ｍｌ、分散剤としての脂肪族アルコールサルフェート０．１ｇとともに、粒度分布測定装置に投入した。投入後、分散用超音波を印加した後（超音波出力４０Ｗ×３０ｓｅｃ）、得られた顆粒の粒度分布を測定した。その結果から、平均粒径およびピーク径を算出したところ、それぞれ４．３２４μｍ、６．０μｍであった。また、上述したピーク径に対して微粉と判断される「粒径２．０μｍの頻度」と、「ピーク径６．０μｍの頻度」とを用いて頻度比を求めた。その結果、分散用超音波を印加した後の頻度比は０．４７であった。
【００４４】
次に、強度判定用超音波印加の条件を表３に示す２段階に設定し、各超音波処理後の顆粒の頻度比を求めた。その値を、それぞれの平均粒径とともに表３に併せて示す。また、表３には、強度判定用超音波印加前後の試料をＳＥＭ（走査型電子顕微鏡）で観察した結果を併せて示している。さらにまた、強度判定用超音波印加にともなう顆粒粒度分布の変化を、図７に示す。
【００４５】
【表３】

【００４６】
ここで、本実験例では、強度判定用超音波印加の条件が８０Ｗ×１ｍｉｎの場合の基準頻度比を０．４７に設定しているものとする。この基準頻度比と、表３に示した強度判定用超音波の出力が８０Ｗ×１ｍｉｎの場合の頻度比を比較すると、この頻度比は基準頻度比より大きい。これにより、この粉体は所望の強度を有しないものと判定することができる。また、図７からは、強度判定用超音波印加にともない当初の正規分布が崩れて、粒径が小さい粒子が大幅に増え、粒度分布が二山分布となっていることが容易に視認できる。
【００４７】
（実験例４）
乾燥条件およびスラリ供給量を以下のように設定した以外は、実験例３と同様の手順で顆粒を作製した。
【００４８】
この顆粒を実験例３と同様の手順で粒度分布測定装置に投入した。投入後、得られた顆粒の粒度分布を測定した。その結果から、平均粒径およびピーク径を算出したところ、それぞれ６．９８３μｍ、７．０μｍであった。また、上述したピーク径に対して微粉と判断される「粒径２．０μｍの頻度」と、「ピーク径７．０μｍの頻度」とを用いて頻度比を求めた。その結果、分散用超音波印加後の頻度比は０．１３であった。
【００４９】
次に、強度判定用超音波印加の条件を表４に示す３段階に設定し、各超音波処理後の顆粒の頻度比を求めた。その値を、それぞれの平均粒径とともに表４に併せて示す。また、表４には、強度判定用超音波印加前後の試料をＳＥＭ（走査型電子顕微鏡）で観察した結果を併せて示している。さらにまた、強度判定用超音波印加にともなう顆粒粒度分布の変化を、図８に示す。
【００５０】
【表４】

【００５１】
図８からは、強度判定用超音波の出力が高くなっても、当初の正規分布の乱れが少ないことがわかる。このことから、実験例４で作製した試料は強度が高いと判定することができる。ここで、表４を見ると、強度判定用超音波の出力が１００Ｗと高くなっても、基準頻度比よりも低い値の０．２３という頻度比を示している。
【００５２】
以上の実験例では、顆粒を用いたが、本実施の形態に係る粉体強度判定装置１０は顆粒以外の粉体の強度を判定する場合にも有効である。例えば、カプセル用の薬品粒子のようなものを強度判定対象とすることもできる。その他、種々様々な粉体に対して、本実施の形態に係る粉体強度判定装置１０を適用することができる。
【００５３】
【発明の効果】
本発明によれば、迅速かつより簡易な方法で、顆粒等の粉体の強度を精度よく判定する技術を提供される。
【図面の簡単な説明】
【図１】本実施の形態に係る粉体強度判定装置の構成の一例を示すブロック図である。
【図２】基準頻度比を設定する際の処理手順を示す図である。
【図３】強度判定用超音波印加にともなう頻度比の変化に基づき、粉体の強度を判定する際の処理手順を示す図である。
【図４】実験例１で測定された強度判定用超音波印加にともなう顆粒粒度分布の変化を示す図である。
【図５】実験例１で測定された強度判定用超音波印加前後の粉体をＳＥＭ（走査型電子顕微鏡）で観察した観察像である。
【図６】実験例２で測定された強度判定用超音波印加にともなう顆粒粒度分布の変化を示す図である。
【図７】実験例３で測定された強度判定用超音波印加にともなう顆粒粒度分布の変化を示す図である。
【図８】実験例４で測定された強度判定用超音波印加にともなう顆粒粒度分布の変化を示す図である。
【符号の説明】
１…粉体収容手段、２…粒度分布測定手段（粒度測定手段）、３…超音波印加手段、４…強度判定手段、５…出力手段、１０…粉体強度判定装置（粒度測定装置）[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a method for determining powder strength and an apparatus for measuring particle size for obtaining an index for evaluating the strength of powder.
[0002]
[Prior art]
In the case of pharmaceutical tablets and ceramic powder metallurgy molded products, it is common to mix the raw material powders uniformly, granulate them, and then tablet or press. If the granulated product is too soft or too hard, sufficient formability cannot be obtained. For this reason, in the field where the strength of a granulated product (granules) determines the quality of a product, it is common practice to measure the strength of granules in advance and use only granules having a predetermined strength. As a method for measuring the strength of granules, there is a method using a micro compression tester. In this method, granules are compressed using a flat indenter, and the deformation and fracture characteristics of the granules are evaluated.
[0003]
By the way, Japanese Patent Application Laid-Open No. 2001-83071 discloses that granules are gas-conveyed in a pneumatic conduit set to a predetermined length, and the granule strength is measured from a change in characteristics of the granules before and after pneumatic conveyance. . This is because the strength of the granules when a force such as crushing from the outside is applied to the granules does not always match the granule strength against the pulverization of the granules when the granules are gas-conveyed, and the granules judged to be strong This is based on the fact that the degree of pulverization is large even when gas is conveyed using, and there are many cases where operation troubles occur during actual use.
[0004]
[Patent Document 1]
JP 2001-83071 A (Claims)
[0005]
[Problems to be solved by the invention]
However, the method for measuring granule strength using the above-mentioned micro compression tester has the following problems. That is, in this method, a breaking strength test is performed on one granule, and in order to grasp the strength of the aggregate of granules used for production, the breaking strength is measured for each granule, and the measurement is performed. The statistics of the results must be taken. Therefore, it takes an enormous amount of time to grasp the strength of the aggregate of granules using this method. Moreover, since the morphology of the granules is different from each other, the measurement results vary widely, and even if the strength of the aggregate of the granules is calculated over an enormous amount of time as described above, the accuracy of the evaluation is insufficient. there were. In recent years, in the field of ceramics, finer powders have been developed, and powders having an average particle diameter of 10 μm or less are often used as raw materials. However, what can actually be measured using a micro-compression tester is one with an average particle size of 80 μm or more, and when the average particle size becomes as fine as 10 μm or less, the powder strength can no longer be increased depending on the micro-compression tester. Cannot be measured.
[0006]
On the other hand, according to the method described in JP-A-2001-83071, the strength of the aggregate of granules can be determined. However, since the characteristics of the granules before and after pneumatic do not change unless the pneumatic conduit is lengthened to some extent, according to the method described in JP-A-2001-83071, an apparatus for measuring granule strength is large. There is a problem that it becomes. Moreover, there is a problem that the granule strength cannot be measured unless the granules are conveyed, in other words, the strength cannot be measured without moving the granules. Furthermore, in Japanese Patent Application Laid-Open No. 2001-83071, a large amount of granules in kilogram units is used to measure the granule strength, and the measurement of the granule strength is extensive.
Accordingly, an object of the present invention is to provide a technique for accurately determining the strength of powder such as granules by a quick and simple method.
[0007]
[Means for Solving the Problems]
In order to solve the above problems, the present inventor has made various studies. As a result, they focused on the fact that the particle size of the powder changes when ultrasonic waves are applied to the aggregate of the powder, and have come to the knowledge that the change in the particle size can be used for determining the strength. That is, according to the present invention, the step of applying ultrasonic waves to the powder whose strength is to be determined, the information (a) relating to the particle size of the powder to which the ultrasonic waves are applied, and the information ( b) comparing with (b).
In the present invention, the information on the particle size includes various information such as a particle size distribution, an average particle size, a peak value of the particle size distribution, and a frequency of particles having a predetermined particle size. As will be described in detail later, the information (b) held in advance on the particle size of the powder widely includes information held on the particle size of the powder regardless of whether or not ultrasonic waves are applied.
[0008]
As one example, the reference powder, that is, the information on the particle size when applying the ultrasonic waves under the same conditions as the ultrasonic waves applied to the powder prepared separately from the powder whose strength is to be measured, It can be used as information (b). The ultrasonic wave under the same conditions as the applied ultrasonic wave specifically means that the ultrasonic output is the same and the application time is the same. Thus, the strength of the powder can be determined by comparing the information on the particle size when the ultrasonic wave is applied under the same conditions.
In this case, a frequency ratio which is a ratio of the frequency of the powder having the second particle size to the frequency of the powder having the first particle size can be used as the information (a) and the information (b) described above. .
[0009]
Further, as the information (b) described above, information on the particle size of the powder before the ultrasonic wave is applied can be used. In other words, the strength of the powder can be determined by comparing information on the particle size of the powder before and after the application of the ultrasonic wave, for example, the average particle size.
In the powder strength determination method according to the present invention, granules can be used as the powder to be subjected to the strength determination. It has been considered that it is difficult to measure the strength of the granules with high accuracy because the morphology of the granules is different from one grain to another. However, according to the method for judging powder strength according to the present invention, the aggregation of such granules is performed. Powder strength as a body can be easily and accurately determined using ultrasonic waves.
It is important that the ultrasonic wave applied in the powder strength determination method according to the present invention can change the form of the powder. Conventional ultrasonic waves applied at the time of powder dispersion for measuring the particle size of powder do not have strong energy enough to change the morphology of the powder. In the present invention using sound waves, there is energy capable of changing the form of the powder.
[0010]
The above-described powder strength determination method can be realized by adding a function for strength determination to an existing particle size measuring device. The existing particle size measuring device measures the particle size distribution after applying ultrasonic waves to the powder to be subjected to the particle size measurement and dispersing the powder. However, in the existing particle size measuring device, the ultrasonic wave is applied for the purpose of agglomerating and dispersing the powder, and the output of the ultrasonic wave is low. Therefore, the present invention provides a novel particle size measuring device having a configuration capable of applying an ultrasonic wave having energy capable of determining the intensity as well as the particle size measurement of the powder. That is, the present invention provides an ultrasonic wave applying means for applying an ultrasonic wave with a first energy or an ultrasonic wave with a second energy higher than the first energy to a powder to be measured; Particle size measuring means for measuring the particle size of the powder to which the ultrasonic wave is applied or the particle size of the powder to which the ultrasonic wave is applied by the second energy, and the particle size of the powder to which the ultrasonic wave is applied by the second energy And a strength determining means for determining the strength of the powder based on the information on the particle size. The particle size measuring device according to the present invention may further include a powder storage unit that stores the powder to be subjected to the particle size measurement. Since the energy of the ultrasonic wave is determined by the output of the ultrasonic wave and the time for applying the ultrasonic wave, whether or not the second energy is higher than the first energy is determined by the output and the application time. As described above, in the particle size measuring device according to the present invention, ultrasonic waves with at least two energies are applied, but the first energy can be used for normal particle size measurement and the second energy can be used for intensity determination. .
[0011]
Further, the above-mentioned ultrasonic wave applying means can apply ultrasonic waves with the first energy or ultrasonic waves with the second energy to the powder stored in the powder storing means. That is, according to the particle size measuring device according to the present invention, normal particle size measurement and strength determination can be performed in the same device.
As an embodiment of the strength determination using the particle size measuring device according to the present invention, the strength determining means holds reference information serving as a reference for the strength determination, and compares this reference information with information on the particle size of the powder. The strength of the powder can be measured. As the reference information, for example, a frequency ratio or a ratio of average particle diameters can be used. Further, it is also possible to measure the strength of the powder by holding the particle size distribution itself as reference information and visually comparing the particle size distribution as information on the particle size of the powder. For example, when the particle size distribution, which was a normal distribution, has changed to a two-peak distribution, a change in the strength of the powder can be easily recognized visually.
[0012]
Further, as another mode of the strength judgment using the particle size measuring device according to the present invention, the following is mentioned. First, the ultrasonic wave applying means applies the ultrasonic wave with the first energy to the powder to be measured, and in response, the particle size measuring means applies the ultrasonic wave with the first energy to the powder to which the ultrasonic wave with the first energy is applied. Measure the particle size. Next, the ultrasonic wave applying means applies the ultrasonic wave with the second energy to the powder, that is, the powder to which the ultrasonic wave with the first energy is applied. Then, the particle size measuring means measures the particle size of the powder to which the ultrasonic wave of the second energy is applied, and the intensity determining means determines the particle size of the powder to which the ultrasonic wave of the first energy is applied and the second energy. And the particle size of the powder to which the ultrasonic wave is applied. Thus, the strength of the powder is measured.
The particle size measuring device according to the present invention may further include an output unit that outputs a determination result by the strength determining unit.
[0013]
BEST MODE FOR CARRYING OUT THE INVENTION
As described above, in the present invention, the ultrasonic wave is applied to the powder, and the information (information (a)) related to the particle size of the powder to which the ultrasonic wave is applied is replaced with the information (information (information ( b)) to determine the strength of the powder. That is, according to the present invention, the strength of the powder can be determined while measuring the particle size. As described above, the information on the particle size of the powder includes various information such as the particle size distribution, the average particle size, the peak value of the particle size distribution, the frequency of particles having a certain particle size, and the like. Hereinafter, a case will be described as an example where the frequency ratio is determined after calculating the particle size distribution and the strength of the powder is determined based on the frequency ratio.
[0014]
First, the configuration of the present invention will be described with reference to FIG.
FIG. 1 is a block diagram illustrating an example of the configuration of the powder strength determination device according to the present embodiment.
As shown in FIG. 1, a powder strength determination device (particle size measurement device) 10 includes a powder storage unit 1 for storing a powder whose strength is to be determined, Means) 2, an ultrasonic wave applying means 3 for applying an ultrasonic wave to the powder, an intensity judging means 4 for judging the strength of the powder based on the particle size distribution measurement result by the particle size distribution measuring means 2, An output unit 5 for outputting a determination result is provided.
[0015]
In the present embodiment, the strength of the powder is not determined by using the powder in the unit of kilogram, but a part of the powder to be used is sampled in the unit of a gram and the strength of the powder is determined. Measure. Therefore, the form of the powder storage means 1 is not particularly limited as long as the size can store the sampled powder. The amount of powder to be sampled depends on the type of powder, but may be about 0.05 to 5 g, or about 0.05 to 2 g in the case of ceramic granules.
In order to measure the particle size of the powder whose strength is to be determined, the powder whose strength is to be determined is stored in the powder storage unit 1 together with about 50 to 300 ml of a dispersion medium. The dispersion medium is selected on the basis that the sampled powder can be dispersed and that no change other than the dispersion is caused in the powder. For example, when measuring the strength of the granules, a dispersion medium is appropriately selected from water or an organic solvent so that the granules are not crushed spontaneously by the dissolution of the binder. Hereinafter, a mixture of the powder to be subjected to the strength determination and the dispersion medium is appropriately referred to as a sample.
[0016]
The particle size distribution measuring means 2 includes a laser irradiator 2a for irradiating the sample with a laser beam, a diffraction detector 2b for detecting diffracted light from powder in the sample, and a particle size based on a diffraction detection result from the diffraction detector 2b. A particle size distribution calculator 2c for calculating the distribution is provided. As a light source in the laser irradiation unit 2a, for example, a semiconductor laser having a wavelength of 700 to 850 nm and an output of 1 to 5 mW can be used.
[0017]
As the ultrasonic wave applying means 3, one capable of oscillating two or more ultrasonic energy is used. More specifically, it is possible to perform ultrasonic application of energy (first energy) suitable for dispersion and ultrasonic application of energy (second energy) suitable for intensity determination at any timing. Is used.
It is desirable that the ultrasonic wave application means 3 be capable of arbitrarily setting the ultrasonic wave output within a range of 20 to 800 W, particularly 40 to 300 W. When the output of the ultrasonic wave applying means 3 is set to about 20 to 40 W, the sample can be ultrasonically dispersed with almost no breakage of the powder (hereinafter, ultrasonic waves are applied for the purpose of dispersion). In this case, it is referred to as “dispersion ultrasonic wave application”). On the other hand, as described later, in the present embodiment, ultrasonic waves are applied to the extent that the form of the powder changes, and the strength of the powder is determined based on a change in the particle size distribution due to the application of the ultrasonic waves (hereinafter, the powder strength is determined). When applying ultrasonic waves for the purpose of measuring the strength of the body, this is referred to as “application of ultrasonic waves for intensity determination”. Therefore, the ultrasonic wave applying means 3 is capable of performing ultrasonic processing at a high output and has a large output width, that is, the ultrasonic output is arbitrarily set within the range of 20 to 800 W as described above. What is possible is desirable. Further, in the present embodiment, the one in which the amplitude of the vibrator increases with the increase in the ultrasonic output can be used as the ultrasonic wave applying means 3.
The differentiation between the ultrasonic waves for dispersion and the ultrasonic waves for intensity determination may be appropriately performed depending on the type of the powder and the like. For example, it is not always necessary to set the output of the ultrasonic waves for dispersion within the range of 20 to 40 W. Sound waves can also be used.
[0018]
The strength determining means 4 holds reference information serving as a reference for strength determination, and determines the strength of the powder by comparing the reference information with information on the particle size of the powder. For example, it is assumed that a reference frequency ratio (hereinafter, referred to as “reference frequency ratio”) is stored therein as reference information. In this case, the reference frequency ratio and information on the particle size of the powder to which the ultrasonic wave for intensity determination under the same condition as the ultrasonic wave applied when calculating the reference frequency ratio is applied, for example, particle size distribution measuring means By comparing with the frequency ratio obtained in step 2, it is determined whether the strength of the powder is high or low. The reference frequency ratio is set in association with the ultrasonic processing conditions, that is, the ultrasonic output and the ultrasonic application time. In addition, the strength determination means 4 can hold a plurality of pieces of reference information, and can use different pieces of reference information to be used according to the type of the powder whose strength is to be determined. For example, whether the reference information is used depending on whether the powder is used for producing a spherical powder for a molded product of ceramic powder metallurgy or a powder used for producing a drug particle for a capsule, or the like. Good.
[0019]
Here, the frequency ratio can be calculated using the frequency of the first particle size of the powder and the frequency of the second particle size of the powder. As the first particle size, a peak diameter of the powder can be used. On the other hand, as the second particle size, a particle size that can be determined as fine powder in the powder, for example, a 20% diameter can be used. By calculating the frequency ratio using the peak diameter and the diameter smaller than the peak diameter, it is possible to easily determine how much the pulverization has progressed. In particular, when the powder is a granule, the granule is gradually broken with the application of the ultrasonic wave for intensity determination, and the primary particles appear, but the particle size assumed as the particle size of the primary particles is changed to the second particle size. If the frequency ratio is calculated using the particle size, the degree of destruction of the granules can be easily grasped without performing microscopic observation. As described above, it is preferable to use the second particle size that can be determined as a fine powder in the powder, but the first particle size is not limited to the peak diameter, but may be the average particle size before the application of the ultrasonic wave for intensity determination or the like. And any value can be used as appropriate.
[0020]
The output unit 5 outputs a result of the determination by the intensity determination unit 4. It is desirable that the output unit 5 has a known print output function and further has a drawing function.
[0021]
Next, the operation of the powder strength determination device 10 according to the present invention will be described.
First, in the powder strength judging device 10 shown in FIG. After the introduction, ultrasonic waves for dispersion are applied to uniformly disperse the powder in the sample and accurately measure the particle size distribution. Next, by performing a predetermined operation, the sample stored in the powder storage unit 1 is irradiated with a laser beam from the laser irradiation unit 2a. When the laser irradiation unit 2a irradiates the sample with the laser beam, the diffracted light from the powder in the sample is focused on the diffraction detection unit 2b by the lens. Since this diffraction pattern has a light intensity distribution corresponding to the particle size distribution of the powder in the sample, the particle size distribution calculation unit 2c calculates the light intensity distribution detected by the diffraction detection unit 2b. The particle size distribution of the powder is measured. Note that the calculated particle size distribution is held in the particle size distribution calculation unit 2c.
[0022]
When the measurement of the particle size distribution to which the ultrasonic waves for dispersion have been applied is completed, the ultrasonic wave applying means 3 applies ultrasonic waves for intensity determination having a predetermined output to the sample for a certain period of time. The application time is appropriately determined, for example, in the range of 0.5 to 10 minutes based on the output of the ultrasonic wave. After the application of the ultrasonic wave for intensity determination by the ultrasonic wave applying means 3, the particle size distribution measuring means 2 measures the particle size distribution of the powder again. At this time, whether to apply the ultrasonic waves for dispersion may be appropriately determined for each sample.
[0023]
After the measurement of the particle size distribution of the powder after application of the ultrasonic waves for intensity determination, the intensity determination means 4 determines the intensity of the powder based on the reference frequency ratio. The setting method of the reference frequency ratio will be described later, but the reference frequency ratio is set in association with the condition of the ultrasonic processing. For example, when the ultrasonic processing of 100 W × 1 min is associated with the reference frequency ratio, by comparing the frequency ratio measured after the ultrasonic wave for intensity determination under the same condition is applied with the reference frequency ratio, The strength determining means 4 determines the strength of the powder.
[0024]
In addition, the intensity determining means 4 indicates how much the frequency ratio of the powder to which the intensity determining ultrasonic wave is applied after the dispersion ultrasonic wave is applied to the frequency ratio of the powder to which the ultrasonic wave for dispersion is applied. , The strength of the powder can be determined. That is, when the frequency ratio of the powder in the state where the ultrasonic wave for dispersion is applied is 0.1, and the frequency ratio of the powder after the ultrasonic wave for intensity determination is applied is 0.2, The rate of change is 200%. Here, if the change rate under the predetermined ultrasonic wave application condition is within 150%, the strength of the powder is determined to be high, and the reference change rate is held as one piece of reference information. The strength of the powder can be determined in the same manner as when the above-described reference frequency ratio is used.
When the determination by the strength determining unit 4 is completed, the output unit 5 outputs the determination result. This output may be only that the strength of the powder is high or low, or in the form of outputting data of the average particle diameter of the powder or data of the frequency ratio as shown in an experimental example described later. There may be.
[0025]
Next, a processing procedure for setting the reference frequency ratio will be described with reference to FIG. This processing is performed by the particle size distribution measuring means 2 and the strength determining means 4 in cooperation with each other when the powder whose strength is to be determined is stored in the powder storing means 1.
[0026]
<Process of setting reference frequency ratio>
As shown in FIG. 2, first, in step S201, the ultrasonic wave applying means 3 applies an ultrasonic wave to the sample with the output A. In the following step S203, the particle size distribution measuring means 2 calculates the frequency ratio A of the powder in the case of the output A. The frequency ratio A measured in step S203 is sent to the intensity judging means 4 and held therein. The processing in steps S201 and S203 can be performed while the powder is stored in the powder storage unit 1. The output A may be an output suitable for dispersion.
A sample that has already been subjected to the ultrasonic treatment with the output A is extracted from the powder storage unit 1 and a new sample is placed in the powder storage unit 1, and then the process proceeds to step S205. In step S205, the ultrasonic wave application means 3 applies an ultrasonic wave to the sample at the output B. Here, it is assumed that the value of the output B is larger than the value of the output A. In the following step S207, the particle size distribution measuring means 2 calculates the frequency ratio B of the powder in the case of the output B. The frequency ratio B measured in step S207 is also sent to the intensity determination means 4 and held therein.
After the sample subjected to the ultrasonic processing at the output B is extracted from the powder containing means 1 and a new sample is put into the powder containing means 1, the process proceeds to step S209. In step S209, the ultrasonic wave application means 3 applies an ultrasonic wave to the sample with the output C. Here, it is assumed that the value of the output C is larger than the value of the output B. In the following step S211, the particle size distribution measuring means 2 calculates the frequency ratio C of the powder in the case of the output C. The frequency ratio C measured in step S211 is also sent to the intensity determination means 4 and held therein.
[0027]
By the above processing, three frequency ratios, that is, the frequency ratio A for the output A, the frequency ratio B for the output B, and the frequency ratio C for the output C are held inside the intensity determination unit 4. The Rukoto. In a succeeding step S213, a reference frequency ratio is set. Here, for example, it is assumed that the frequency ratio A for the output A is 0.2, the frequency ratio B for the output B is 0.25, and the frequency ratio C for the output C is 0.4. In this case, the frequency ratio C in the case of the output C in which the frequency ratio greatly changes with respect to the frequency ratio A can be set as the reference frequency ratio, and the output of the reference ultrasonic wave can be set as the output C. When a plurality of reference frequency ratios are set, for example, the frequency ratio C for the output C is set as the reference frequency ratio, and the frequency ratio B for the output B is set as the reference frequency ratio. Is possible. Here, the processing procedure for setting the reference frequency ratio has been described by taking as an example the case where the ultrasonic waves are changed in three stages of the outputs A to C. However, the reference frequency ratio is determined by changing the stages in four or more stages. Or two steps in reverse.
[0028]
<Process of determining powder strength>
Further, as described above, the strength determining means 4 determines the strength of the powder by comparing the frequency ratio of the powder to which the ultrasonic wave for strength determination is applied with the reference frequency ratio. The processing procedure at this time will be described with reference to FIG. This process is performed after the reference frequency ratio is set. Further, here, the following description will be made assuming that the reference frequency ratio in the case of the output C is set to 0.4. Further, it is assumed that the frequency ratio is measured on the basis that it is determined that the smaller the frequency ratio is, the higher the strength of the powder is, and the larger the frequency ratio is, the lower the strength of the powder is.
[0029]
As shown in FIG. 3, first, in step S301, the ultrasonic wave application means 3 applies an ultrasonic wave for intensity determination under the same condition as the ultrasonic wave of the output C as a reference to the sample. In the following step S303, the particle size distribution measuring means 2 measures the particle size distribution of the powder in the sample.
Next, in step S305, a frequency ratio in the output C is calculated based on the particle size distribution measured in step S303. This frequency ratio is sent to the intensity judging means 4 and held therein.
In step S307, the intensity determination unit 4 compares the frequency ratio calculated in step S305 with the reference frequency ratio. Here, it is assumed that the calculated frequency ratio is 0.3 when the reference frequency ratio is set to 0.4 as described above. In this case, since the calculated frequency ratio is smaller than the reference frequency ratio, it is determined that the strength of the powder is high. On the other hand, when the reference frequency ratio is set to 0.4 as described above, the calculated frequency ratio is assumed to be 0.5. In this case, since the calculated frequency ratio is larger than the reference frequency ratio, it is determined that the strength of the powder is low.
After the determination in step S307, this determination result is output by the output means 5 (step S309).
[0030]
As described above, the powder strength determination device 10 according to the present embodiment can easily determine the strength of the aggregate of the powder in the manner of measuring the particle size of the powder. FIG. 2 shows a case where the reference frequency ratio is set based on three frequency ratios A to C by changing the output of the ultrasonic wave in three stages. However, the time for applying the ultrasonic wave may be several minutes each. Therefore, the time required for setting the reference frequency ratio is very short. According to the powder strength determination device 10 of the present embodiment that measures the strength of the powder using predetermined reference information such as the reference frequency ratio, the strength of the powder can be determined in a short time and with high accuracy. . Moreover, since the amount of powder required for the measurement may be only a few gram units, the measurement can be performed using a small device, which is excellent in convenience. Further, according to the powder strength determining apparatus 10 according to the present embodiment, the strength of fine powder having an average particle diameter of 10 μm or less, which cannot be measured by a conventional micro compression tester, is also determined. It is possible to do.
[0031]
Note that the procedure for setting the reference frequency ratio is not limited to the above. In addition, the reference frequency ratio has been described as an example, but the present invention is not limited to the frequency ratio, and a ratio of average particle diameter, a ratio of peak values of the particle size distribution, and the like may be used instead of the reference frequency ratio.
Further, an example has been described in which the strength of the powder is determined after the reference frequency ratio as the reference information is determined in advance, but the method of determining the strength of the powder is not limited to this. For example, prior to the ultrasonic wave processing for intensity determination shown in FIG. 3 (step S301), the particle size distribution of the sample to which only the ultrasonic wave for dispersion is applied is measured in advance, and the frequency ratio of the powder is calculated. By comparing the powder frequency ratio calculated in step S305 with the powder frequency ratio, the powder strength may be grasped.
[0032]
【Example】
Hereinafter, examples in which the strength of the powder is measured by applying ultrasonic waves for intensity determination will be described as Experimental Examples 1 to 4. In the following experimental examples, the powder strength was evaluated using a particle size distribution analyzer (Microtrack HRA9320-X100 manufactured by Nikkiso Co., Ltd.), an ultrasonic disperser, and an SEM (scanning electron microscope).
(Experimental example 1)
A slurry having a solid content of 60 wt% was prepared using powder having an average particle size of 1.1 μm. A slurry obtained by adding 1 wt% of PVA (polyvinyl alcohol) as a binder to this slurry was granulated by a spray dryer and granulated. The drying conditions and the slurry supply amount were set as follows.
[0033]
0.15 g of the obtained granules was sampled and put into a particle size distribution analyzer together with 100 ml of methanol as a dispersion medium and 0.1 g of aliphatic alcohol sulfate as a dispersant.
The sample was put into a particle size distribution measuring device, and after applying ultrasonic waves for dispersion (ultrasonic output: 40 W × 30 sec), the particle size distribution of the obtained granules was measured. From the results, the average particle diameter and the peak diameter were calculated, and both were 4.6 μm. Further, the frequency ratio was determined using “frequency of 1.5 μm particle size”, which is determined to be fine powder, and “frequency of 4.6 μm peak diameter” with respect to the peak diameter described above. As a result, the frequency ratio after application of the ultrasonic waves for dispersion was 0.155.
[0034]
The conditions for applying the ultrasonic wave for intensity determination were set to the four stages shown in Table 1, and the frequency ratio of the granules after each ultrasonic treatment was determined. The values are shown in Table 1 together with the respective average particle sizes. FIG. 4 shows a change in the particle size distribution of the granules due to the application of the ultrasonic waves for intensity determination.
[0035]
[Table 1]

[0036]
As shown in Table 1, as the output of the ultrasonic wave for intensity determination increases to 60 W, 80 W, 100 W, and 150 W, the frequency ratio gradually increases. This indicates that pulverization is progressing with an increase in the output of the ultrasonic wave for intensity determination. In addition, it can be seen from FIG. 4 that the initial normal distribution is broken and particles having a small particle size are increasing. Here, in this experimental example, it is assumed that the reference frequency ratio when the application condition of the ultrasonic wave for intensity determination is 100 W × 1 min is set to 0.3. When this reference frequency ratio is compared with the frequency ratio when the output of the ultrasonic wave for intensity determination shown in Table 1 is 100 W, this frequency ratio is smaller than the reference frequency ratio. Thereby, it can be determined that this powder has a desired strength.
[0037]
Here, FIG. 5 shows an SEM (scanning electron microscope) observation image. FIG. 5 (a) is a result of observing the powder in a state where ultrasonic waves for dispersion are applied, and FIG. 5 (b) is a result of observing the powder after application of ultrasonic waves for intensity determination of 80 W × 1 min. 5 (c) shows the results of observing the powder after the ultrasonic wave for intensity determination of 150 W × 1 min was applied. From FIG. 5, it can be seen from FIG. 5 that, as a result of the ultrasonic treatment, the granules as a powder are gradually pulverized. It can be seen that the particles have been pulverized into primary particles.
[0038]
(Experimental example 2)
Granules produced under the same conditions in Experimental Example 1 and having both an average particle diameter and a peak diameter of 4.6 μm were charged into a particle size distribution analyzer in the same procedure as in Experimental Example 1. The frequency ratio of this powder after the application of the ultrasonic waves for dispersion was 0.155 as in Experimental Example 1.
[0039]
Next, the conditions for applying the ultrasonic wave for intensity determination were set to three stages shown in Table 2, and the frequency ratio of the granules after each ultrasonic treatment was determined. The values are shown in Table 2 together with the respective average particle sizes. Table 2 also shows the results of observation of the sample before and after the application of the ultrasonic wave for intensity determination with a scanning electron microscope (SEM). FIG. 6 shows a change in the particle size distribution of the granule before and after the application of the ultrasonic wave for intensity determination.
[0040]
[Table 2]

[0041]
As shown in Table 2, as in the case of Experimental Example 1, as the output of the ultrasonic wave for intensity determination increases to 60 W, 80 W, and 100 W, the frequency ratio gradually increases. Also, from FIG. 6, it can be seen that the initial normal distribution has collapsed and particles having a small particle size have increased. Here, in this experimental example, it is assumed that the reference frequency ratio is set to 0.3 when the ultrasonic wave application condition for intensity determination is 80 W × 5 min. When this reference frequency ratio is compared with the frequency ratio when the output of the ultrasonic wave for intensity determination shown in Table 2 is 80 W × 5 min, this frequency ratio is smaller than the reference frequency ratio. Thereby, it can be determined that this powder has a desired strength.
[0042]
(Experimental example 3)
A slurry having a solid content of 57.9% by weight was prepared using powder having an average particle size of 1.1 μm. A slurry obtained by adding 1 wt% of PVA (polyvinyl alcohol) as a binder to this slurry was granulated by a spray dryer and granulated. The drying conditions and the slurry supply amount were set as follows.
[0043]
0.15 g of the obtained granules was sampled and put into a particle size distribution analyzer together with 100 ml of methanol as a dispersion medium and 0.1 g of aliphatic alcohol sulfate as a dispersant. After the introduction, ultrasonic waves for dispersion were applied (ultrasonic output: 40 W × 30 sec), and the particle size distribution of the obtained granules was measured. From the results, the average particle diameter and the peak diameter were calculated to be 4.324 μm and 6.0 μm, respectively. Further, the frequency ratio was determined using “frequency of 2.0 μm particle diameter”, which is determined to be fine powder, and “frequency of 6.0 μm peak diameter” with respect to the above-mentioned peak diameter. As a result, the frequency ratio after application of the ultrasonic waves for dispersion was 0.47.
[0044]
Next, the conditions for applying the ultrasonic wave for intensity determination were set to two stages shown in Table 3, and the frequency ratio of the granules after each ultrasonic treatment was determined. The values are shown in Table 3 together with the respective average particle sizes. Table 3 also shows the results of observation of the sample before and after the application of the ultrasonic wave for intensity determination by a scanning electron microscope (SEM). Further, FIG. 7 shows a change in the particle size distribution of the granules due to the application of the ultrasonic waves for intensity determination.
[0045]
[Table 3]

[0046]
Here, in this experimental example, it is assumed that the reference frequency ratio when the condition for applying the ultrasonic wave for intensity determination is 80 W × 1 min is set to 0.47. Comparing this reference frequency ratio with the frequency ratio when the output of the ultrasonic wave for intensity determination shown in Table 3 is 80 W × 1 min, the frequency ratio is larger than the reference frequency ratio. Thus, it can be determined that the powder does not have the desired strength. Further, from FIG. 7, it can be easily recognized that the initial normal distribution is destroyed by the application of the ultrasonic wave for intensity determination, the particles having a small particle size are greatly increased, and the particle size distribution is a two-peak distribution.
[0047]
(Experimental example 4)
Granules were produced in the same procedure as in Experimental Example 3, except that the drying conditions and the slurry supply amount were set as follows.
[0048]
The granules were charged into a particle size distribution analyzer in the same procedure as in Experimental Example 3. After the introduction, the particle size distribution of the obtained granules was measured. From the results, the average particle diameter and the peak diameter were calculated to be 6.983 μm and 7.0 μm, respectively. The frequency ratio was determined using “frequency of particle diameter 2.0 μm” determined as fine powder with respect to the peak diameter described above and “frequency of peak diameter 7.0 μm”. As a result, the frequency ratio after application of the ultrasonic waves for dispersion was 0.13.
[0049]
Next, the conditions for applying the ultrasonic wave for intensity determination were set at three stages shown in Table 4, and the frequency ratio of the granules after each ultrasonic treatment was determined. The values are shown in Table 4 together with the respective average particle sizes. Table 4 also shows the results of observation of the sample before and after the application of the ultrasonic wave for intensity determination by SEM (scanning electron microscope). FIG. 8 shows a change in the particle size distribution of the granules due to the application of the ultrasonic waves for intensity determination.
[0050]
[Table 4]

[0051]
From FIG. 8, it can be seen that even if the output of the ultrasonic wave for intensity determination becomes high, the disturbance of the initial normal distribution is small. From this, it can be determined that the sample manufactured in Experimental Example 4 has high strength. Here, looking at Table 4, even if the output of the ultrasonic wave for intensity determination is as high as 100 W, a frequency ratio of 0.23 which is lower than the reference frequency ratio is shown.
[0052]
In the above experimental example, granules are used, but the powder strength determining apparatus 10 according to the present embodiment is also effective when determining the strength of powder other than granules. For example, a drug such as a capsule drug particle can be used as a strength determination target. In addition, the powder strength determination device 10 according to the present embodiment can be applied to various kinds of powder.
[0053]
【The invention's effect】
ADVANTAGE OF THE INVENTION According to this invention, the technique of judging the intensity | strength of powders, such as granules, accurately with a quick and simple method is provided.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an example of a configuration of a powder strength determination device according to the present embodiment.
FIG. 2 is a diagram showing a processing procedure when setting a reference frequency ratio.
FIG. 3 is a diagram showing a processing procedure when judging the strength of a powder based on a change in a frequency ratio accompanying the application of an ultrasonic wave for intensity judgment.
FIG. 4 is a diagram showing a change in the particle size distribution of granules measured in Experimental Example 1 with the application of ultrasonic waves for intensity determination.
FIG. 5 is an observation image obtained by observing a powder before and after the application of the ultrasonic wave for intensity determination measured in Experimental Example 1 with a scanning electron microscope (SEM).
FIG. 6 is a diagram showing a change in the particle size distribution of granules measured in Experimental Example 2 with the application of ultrasonic waves for intensity determination.
FIG. 7 is a diagram showing a change in the particle size distribution of granules accompanying the application of the ultrasonic waves for intensity determination measured in Experimental Example 3.
FIG. 8 is a diagram showing a change in the particle size distribution of granules measured in Experimental Example 4 with the application of ultrasonic waves for intensity determination.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Powder accommodating means, 2 ... Particle size distribution measuring means (particle size measuring means), 3 ... Ultrasonic wave applying means, 4 ... Intensity judging means, 5 ... Output means, 10 ... Powder strength judging apparatus (particle size measuring apparatus)

Claims (11)

Applying ultrasonic waves to the powder whose strength is to be determined,
Comparing the information (a) about the particle size of the powder to which the ultrasonic wave is applied and the information (b) about the particle size of the powder held in advance,
A powder strength determination method, comprising: 2. The method according to claim 1, wherein the information (b) is information on a particle size when an ultrasonic wave having the same condition as the ultrasonic wave is applied to a reference powder. 3. . The powder according to claim 2, wherein the information (a) and the information (b) are a ratio of a frequency of the powder having the second particle size to a frequency of the powder having the first particle size. Body strength determination method. The method according to claim 1, wherein the information (b) is information on a particle size of the powder before the ultrasonic wave is applied. The method according to any one of claims 1 to 4, wherein the powder is a granule. The method according to claim 1, wherein the applied ultrasonic wave can change a form of the powder. Ultrasonic applying means for applying ultrasonic waves with a first energy or ultrasonic waves with a second energy higher than the first energy to a powder to be measured;
Particle size measuring means for measuring the particle size of the powder to which the ultrasonic wave with the first energy is applied or the particle size of the powder to which the ultrasonic wave with the second energy is applied,
Strength determining means for determining the strength of the powder based on information on the particle size of the powder to which the ultrasonic wave by the second energy is applied,
A particle size measuring device comprising: Further comprising a powder containing means for containing the powder of the particle size measurement target,
The ultrasonic wave applying means applies ultrasonic waves with the first energy or ultrasonic waves with the second energy to the powder contained in the powder containing means. A particle size measuring device according to claim 7. The particle size measuring device according to claim 7, wherein the strength determining unit holds reference information serving as a reference for strength determination, and compares the reference information with information on a particle size of the powder. The ultrasonic wave applying means applies ultrasonic waves with the first energy to the powder to be measured,
The particle size measuring means measures the particle size of the powder to which the ultrasonic wave by the first energy is applied,
Next, the ultrasonic wave applying means applies ultrasonic waves with the second energy to the powder,
The particle size measuring means measures the particle size of the powder to which the ultrasonic wave by the second energy is applied,
The said intensity | strength determination means compares the particle size of the powder to which the ultrasonic wave by the said 1st energy was applied, and the particle size of the powder to which the ultrasonic wave by the said 2nd energy was applied, The Claims characterized by the above-mentioned. The particle size measuring device according to 7 or 8. The particle size measuring device according to claim 7, further comprising an output unit that outputs a result of the determination by the intensity determining unit.

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