Particle size analysis visualizes and measures particle size distribution where every particle has a specific shape and volume with certain sizes and shapes being optimal for a specific process. Particle size analysis is therefore a standard procedure in many quality control and research labs to ensure the highest quality final product.
The most common methods that are used today to determine the particle size are dynamic image analysis (DIA), static image analysis, static laser light scattering (SLS, also called laser diffraction), dynamic light scattering (DLS) and sieving.
Meeting industry requirements, particle size analysis has rapidly evolved from milling, sieving and other material processing techniques in recent years to speed up the particle characterization process while ensuring complete accuracy every time. Today, three different particle sizing methods are commonly applied in laboratories and organisations around the world.
Microtrac manufactures and supplies high-quality and affordable instruments for any of the five commonly used processes – dynamic and static image analysis, laser diffraction, DLS and sieving (via our sister company Retsch).
For particles ranging in size from 0.8 µm to 135 mm, Dynamic Image Analysis (DIA) offers a high-quality alternative to the particle size analysis via sieving or by laser diffraction.
Modern DIA solutions (conforming to ISO 13322-2) such as Microtrac's CAMSIZER range are capable of analysing hundred of images per second in real time. These instruments can therefore detect and characterise millions of individual particles in only a few minutes.
Microtrac’s CAMSIZER range uses a high-speed, high-resolution dual camera system each with an ultrabright LED stroboscopic light source and short exposure times to capture hundreds of images per second (device-dependent). One of two digital cameras is optimised to analyse the small particles in high resolution (ZOOM camera) while the other is used to detect the large particles with a large field of view (BASIC camera). User-friendly powerful software analyses the size and shape of each particle calculating the respective distribution curves.
The main strength of Dynamic Image Analysis is the ability to measure width, circle equivalent diameter, and length of any particle and to provide a size distribution based on the respective parameter. Furthermore, particle shape is characterized based on different shape descriptors including aspect ratio, circularity, symmetry, convexity, and roundness.
Solutions from Microtrac that employ DIA to analyse particle sizes were first brought to market over two decades ago by Retsch Technology who are now known as Microtrac. In those intervening years the technology has been steadily improved, the software continually developed and the range today includes models aimed at the wet & dry analysis of suspensions and powders, the dry analysis of granulates and bulk materials and an online system that can be integrated with 3rd party sample delivery devices.
Microtrac now offers dry and wet Static Image Analysis via their CAMSIZER M1 solution which is capable of determining particle size and shape in a measurement range of between 0.5 µm - 1500 µm. The static sample allows for excellent image quality with rich detail thanks to the high-resolution camera.
Static laser light scattering (SLS) is more commonly known as Laser Diffraction (LD) as well as being referenced from time to time as laser diffractometry, Fraunhofer diffraction or Mie Scattering.
During the interaction of the laser light with particles, diffraction, refraction, reflection and absorption result in light scattering patterns characteristic for the particle size. It is therefore an indirect method which calculates particle size distributions on the basis of superimposed scattered light patterns caused by a whole collective of particles of which one should know the optical characteristics of the material (refraction index) for small particles to obtain reliable results.
The use of Laser Diffraction (LD) for particle size measurement has seen rapid adoption for quality control in both research and industrial environments thanks to the easy operability and versatility of the technique. It is now the de-facto standard for many who have a requirement for particle size analysis.
As it relies on a laser beam illuminating a well-dispersed sample, the size distribution is calculated from the resulting scattered light pattern. There is an assumption that all particles are spherical so the determination of particle shape parameters is not possible.
Powerful software and extremely accurate light signal detection has handed a competitive edge to material processing businesses in sectors including chemical, foodstuffs, fertilizer and pharmaceutical who rely on Laser Diffraction. They have been able to dramatically increase throughput speeds as the relatively limited resolution has to date not proved to be a major issue for them.
Dynamic Light Scattering (DLS) determines the Brownian Motion of submicrometer particles in a suspension. The diffusion rate is directly linked to particles size and can be determined with the Stokes-Einstein equation, which also considers temperature and viscosity of the carrier fluid.
The movement of the particles causes intensity fluctuations in the scattered light. The detection and evaluation of this signal by Fourier transformation allows a reliable measurement of the particle size.
This method is especially suitable for the particle size analysis of nanomaterials. Microtrac uses a unique probe technology for DLS measurement, which is characterized by high flexibility and excellent signal strength.
Sieving (sometimes referred to as a gradation test) is perhaps the simplest way to assess particle size distribution. Sieving is useful for particles of several microns to tens of millimetres in size whether the material is organic or non-organic.
Test sieves such as those manufactured by Retsch (a sister Verder Scientific company) provide a simple cost-effective mechanical method of distributing granules into particle size classes preparing them for further analysis as each sieve in a stack has a progressively smaller mesh size. The test sieves site on a sieve shaker whether that be vibratory for a throwing motion with angular momentum, by employing a horizontal circular motion (sometimes with tapping) or with dispersion by an air jet.
For many companies the use of sieves is an entry point to the world of particle size analysis and particle characterization. It is cost effective particularly for those who might not need to characterize materials on a regular basis or where budgets are highly constrained and time taken is not an issue.
Ultimately, the choice of whether to use a simple sieving solution or to invest in Laser Diffraction or Dynamic Image Analysis will depend on the volume of testing, the budgets and staffing available and any specific international standards or customer requirements that you face.
Why not contact Microtrac for a free consultation to find out which solution will deliver the outcome and the Return on Investment you need?