Palas® U-SMPS (Universal Scanning Mobility Particle Sizers) have been successfully used worldwide for many years for the precise selection of particle size with simultaneous measurement of the particle concentration of airborne particles in the sub-micron range. They make an essential contribution to research/development as a measuring instrument for determining the efficiency of filter media and elements and in the environmental field for determining the concentration and size of ultrafine particles.
Depending on the combination of classifying column (DMA), control unit (DEMC), and particle counter, they cover ranges from a few nanometers to several micrometers. Different combinations are possible depending on the application and customer requirements.
The maximum possible resolution is 128 channels/decade. Combined with an optical particle counter, the upper limit can be extended to 40 µm (U-Range System: U-SMPS System + Fidas® System or Promo® System).
Palas® U-SMPS System can be operated directly with max. two different counters and also accepts third-party products of well-known manufacturers for direct comparison.
Universal scanning mobility particle sizer for high concentrations of 8 – 1200 nm
The Palas® universal scanning mobility particle sizer (U-SMPS) for high aerosol concentrations is available in two versions. The long classifying column (2700 model) is able to reliably determine particle size distributions of 8 to 1,200 nm.
The Palas® U-SMPS system includes a classifier [defined in ISO 15900 as a differential electrical mobility classifier (DEMC), also known as a differential mobility analyzer (DMA)], in which aerosol particles are selected according to their electrical mobility and passed to the outlet. The electrical charges carried by these particles are then measured in a downstream Charme®aerosol electrometer .
A major advantage of aerosol electrometers includes the fact that they enable very rapid measurements. However, this method requires a rather high number of charges. This limits the applicability to high aerosol concentrations (e.g. downstream from a combustion process or particle generator). The measurement of the charge per time unit (flow) is directly traceable to physical parameters. As a result, this method is primarily used as a reference during calibration of condensation particle counters (e.g. UF-CPC).
The U-SMPS is operated using a graphical user interface on a touch screen. One particle distribution scan can be performed in as few as 30 seconds or in up to 64 size channels per decade, during which the voltage in the DEMC classifier is varied continuously, resulting in higher count statistics per size channel. The integrated data logger allows linear and logarithmic display of the measured values on the device itself. The enclosed evaluation software provides various data evaluation (extensive statistics and averaging) and export capabilities.
The U-SMPS is typically operated as a stand‐alone device, but can also be connected to a computer or network using various interfaces (USB, LAN, WLAN, RS-232/485). The Palas® U-SMPS universally supports DMAs, CPCs, and aerosol electrometers from other manufacturers.
Accurate size determination and reliable performance of the U-SMPS are extremely important especially for calibrations. All components are required to pass strict quality assurance testing and are assembled in‐house.
Figure 2 presents the principle of operation of the U-SMPS:
Figure 2: Principle of operation of the universal scanning mobility particle sizer (U-SMPS) with an aerosol electrometer as the concentration measuring device
The aerosol is conditioned before it enters the classifier (DEMC column). An optional dryer (e.g. silica gel, Nafion) removes moisture from the particles. A bipolar neutralizer (e.g. Kr 85) is used to ensure a defined charge distribution of the aerosol. An impactor at the inlet of the DEMC is required in order to remove particles larger than the classifier size range.
The aerosol is then directed into the DEMC column via the inlet. The aerosol flow along the outer electrode is carefully combined here with a sheath air flow. It is important to avoid any turbulence here in order to ensure laminar flow. The surfaces of the electrodes must be of extremely high quality with respect to smoothness and tolerances.
This sheath air is a dry, particle-free carrier gas (typically air) with a higher volume than the aerosol that is continuously circulated in a closed loop. The sheath air to sample air volume ratio defines the transfer function and thus the resolution capacity of the size classifier.
A radially symmetric electric field is generated between the inner and outer electrode by applying voltage. The inner electrode is positively charged with a small slit at the end. By balancing the electrical force on each particle with its aerodynamic drag force in the electrical field, negatively charged particles are diverted to the positive electrode. Depending on their electrical mobility, some of the particles pass through the slit and exit the DEMC.
During operation, the voltage and thus the electrical field change continuously. As a result, particles with varying mobility exit the DEMC and are measured consecutively by a nanoparticle counter – shown here as an aerosol electrometer (e.g. Palas® Charme®).
A back-transformation is necessary in order to combine the data (voltage, charge number, charge distribution, etc.) and obtain a particle size distribution. The algorithm used for this purpose was developed by Prof. Wiedensohler from the IfT (Leipzig, Germany).
Figure 3: Particle size distributions of an aerosol generated by the Palas® DNP 3000 particle generator on the touch screen
User interface and software
Based on continuous customer feedback, the user interface and software have been designed for intuitive operation and real-time control and display of measurement data and parameters.
In addition, the software provides data management with the integrated data logger, sophisticated export capabilities, and network support. The measured data are able to be displayed and evaluated with many available options.
Figure 4 presents the two combinations of the DEMC and Charme® aerosol electrometer available from Palas® . For combinations of the DEMC classifier with Palas® condensation particle counters, please read the "U-SMPS 1xx0_2xx0_V0011212" data sheet. Most DMAs, CPCs, and aerosol electrometers from other manufacturers are able to be used as components of the U-SMPS system.
Figure 4: Overview of the Palas® U-SMPS systems for high concentrations
Your special advantages
- Particle size distributions from 8 to 1.2 nm
- Continuous and fast-scanning principle of measurement
- High resolution in up to 64 size classes/decade
- Suitable for concentrations of up to108 particles/cm3
- Universally connects to DMAs and nanoparticle counters from other manufacturers
- Graphic display of measurement values
- Intuitive operation using 7" touchscreen and GUI
- Integrated data logger
- Supports multiple interfaces and remote access
- Low maintenance
- Reliable function
- Reduces your operating expenses
Individual solutions for various industries
- Filter test
- Aerosol research
- Inhalation experiments
- Workplace measurements
- Measurement range (number C_N)
- 105 – 108 Partikel/cm3
- Size channels
- Max. 256 (128/decade)
- Measurement range (size)
- 6 – 1,200 nm
- User interface
- Touchscreen, 800 • 480 pixel, 7" (17.78 cm)
- Data logger storage
- 4 GB
- Adjustment range (voltage)
- 1 – 10,000 V
- Volume flow (sheath air)
- 2.5 – 14 l/min
- Installation conditions
- +5 – +40 °C (andere auf Anfrage)
- Data Management
- Prepared for connection to the Palas®Cloud MyAtmosphere ("MyAtmosphere-ready"); internet access and separate registration required.MyAtmosphere terms and conditions of use apply.