The core of PerkinElmer’s headspace is our patented pressure-balance technology that far surpasses valve and loop in performance when it comes to accuracy and repeatability. Pressure-balance provides rapid transfer of analytes to the GC without re-equilibration in a gas-sampling valve or syringe and minimizes loss of analytes. Injection amount is programmable by time or by volume without requiring any hardware change.
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High capacity, automated headspace sampler with built-in trap and standard PerkinElmer 9mL or 22mL sample vials. Up to 110 vials can be loaded into the removable vial magazine for automated analysis. Overlapping thermostatting of up to 12 vials in Constant Mode for maximum productivity. An algorithm adjusts the virtual oven size for maximum throughput.
Programmable power-saving and gas-saving Economy Mode comes standard on all models. Automatic system and vial leak checks performed before analysis provide assurance of precision and sensitivity. All models with the built-in trap include programmable pneumatic control. A kit is available to offer safe use of hydrogen as a carrier gas. An optional frequency-scanning shaker is available to reduce equilibration time. Internal standard addition is available for trap models.
|Maximum Temperature||Oven Max Temp 210 °C|
|Minimum Temperature||Oven Min Temp 35 °C|
|Product Brand Name||TurboMatrix|
Butylated hydroxytoluene (BHT) is a common food additive used to protect foods from spoilage. Concern exists that long-term human consumption of BHT may have potential health risks. Analysis of BHT is needed for both food quality and safety reasons.
Epichlorohydrin, a raw material found in resins, can occur in drinking water at concentration which are hazardous to human health. The use of ephichlorohydrin is increasingly regulated. This article presents an analytical technique to determine the concentration of epichlorohydrin in the drinking water, in response to the requirements of the European Normative 98/83/EC, which recommends limiting the concentration to a maximum of 0.1 ug/L.
This application note demonstrates the use of a new sample-introduction technology incorporated in TurboMatrix HS-110 Trap for U.S. EPA Method 8260B for analysis, identification and quantification of volatile organic compounds (VOCs) that have boiling points below 200 °C.
Today’s plastics are some of the most used materials on a global volume basis. Broadly integrated into today’s industrial and commercial lifestyles, they make a major, irreplaceable contribution to virtually every product category.
In this compendium you will find a wide range of applications for polymers, plastics, rubbers and advanced materials. Discover how to put these applications to work for you simply and efficiently.
To meet the growing demand for personal protective equipment following the beginning of the COVID-19 pandemic, face mask production from existing and new manufacturers increased drastically. Testing masks to confirm they do not contain chemical residues, such as volatile organic compounds (VOCs), that may off-gas during normal wear is an integral part of this quality control process. This application note presents a method based on ISO-18562 and ISO-10093 to detect and quantify VOCs in face masks. Utilizing a solvent-free headspace extraction and GC/MS analysis, this method is ideal for PPE producers seeking a quick and precise method to ensure safety and quality standards are met during the production process.
ASTM International publishes a number of different methods for the determination of volatile compounds in water-based coatings. Method D3960 is a gravimetric technique where a sample of known weight is baked under specific conditions; the % weight of volatile organic compounds (VOCs) is calculated from a series of measured masses. The method that was presented here will reliably analyze difficult compounds in a difficult matrix with great precision, linearity, and without carryover.
Journal of Chromatographic Science - A new analytical method for the determination of halogenated and aromatic volatile organic compounds in groundwater, mineral water, and drinking water at concentrations ranging between 1–10000 ng/L is developed..
The development of methodology to measure VOCs at low levels using GC-MS coupled with Headspace Trap sample introduction is described here. The methodology is based on U.S. EPA Method 8260B.
Increasing demands for efficiency, productivity, data quality, and profitability pose ongoing challenges for lubricant testing labs, like yours. Whether you need to achieve quick turnaround times, minimize downtime, or maximize lab efficiencies, you can rely on PerkinElmer for a comprehensive set of simple-to-use and proven testing solutions to help you achieve accurate results in record time. Learn more about our solutions.
Headspace gas chromatography offers an efficient sample-preparation technique that can save both time and money in the analysis of VOCs in a number of matrices. Headspace sampling is a separation technique which allows for the extraction of headspace vapor from a sealed sample, with subsequent injection directly into a GC. The technique obviates the need for time consuming and expensive solvent extractions, while also reducing the potential for human error in sample extraction.
PerkinElmer's TurboMatrix™ Headspace (HS) and Headspace Trap samplers utilize an array of proven technologies to ensure they deliver outstanding precision in any application. Learn more about PerkinElmer's HS solutions for up to 110 vials by downloading this brochure.
This field application report describes the use of a TurboMatrix™ HS-110 Trap and Clarus® 500 GC/MS optimized for low-level determination of fuel oxygenates by U.S. Environmental Protection Agency Method 8260B using the new headspace-trap technology.
2,4,6-trichloroanisole (TCA) is found in the cork used to seal glass wine bottles. The determination of TCA in wine is necessary due to the extremely low level of sensory perception for this compound. The literature reports taste thresholds to be between 4 and 10 parts per trillion (ppt) in white wines and between 10 and 30 ppt for the heavier red wines.1 Above these thresholds, wines have an undesirable flavor.
Increasing demands for efficiency, productivity, data quality, and profitability pose ongoing challenges for lubricant testing laboratories, like yours, performing new lubricant or in-service oil analyses.
Whether you need to achieve quick turnaround times, minimize downtime, or maximize lab efficiencies, you can rely on PerkinElmer as a trusted partner for simple-to-use and reliable testing solutions.
Partnering with leading global standards organizations and hundreds of oil laboratories, we continually address laboratory needs and ever-changing standards while developing new methods and protocols that conform with ASTM®, regulatory, and customer-defined requirements.
Download this infographic to learn more about our broad range of proven lubricant testing solutions.
Consumables reference guide for the TurboMatrix Headspace. TurboMatrix Headspace and high-sensitivity Headspace Trap samplers provide unparalleled precision and ease of use for numerous GC or GC/MS volatile-analysis applications. The system can manage up to 12 samples simultaneously, ensuring that the next sample is ready for analysis upon completion of the previous run, achieving significant time savings.
The Polymer Market consists of a huge diversity of manufacturers of industrial products running many different processes yet still facing similar challenges. There is more and more pressure to achieve high product quality and reduce costs in order to stay one step ahead of the competition.
Product Certificate for the TurboMatrix Headspace HS110/HS16/HS40