Classification of Burners and Their Industry Application
Classification of Burners and Their Industry Application
Burners refer to a device that mixes fuel and air and ignites them in a certain way. They are classified into industrial, civilian, and special types according to their types and application areas. They are usually made of corrosion-resistant and high-temperature materials such as stainless steel or titanium. Their function is to atomize sample material by combustion flames.
During the combustion process, a liquid reagent atomized in a burner, is subject to effects of flame temperature and flame atmosphere, undergoing processes such as drying, melting, evaporation, dissociation, producing a large number of elementary atoms, as well as excited atoms, ions, and molecules. Designated burners should have characteristics such as high atomization efficiency, low noise, and stable flame performance to ensure high sensitivity and precision for mass spectrometry analysis.
Mitosis caused by radiation leaks has attracted interest for both materials researchers and solar scientists, due to the strong effects that this effect can have on both individual atomic centers as well as their binding energy and that these effects are in general temperature independent. Furthermore, recent works show that although temperature-independent effects may have strong gradients due to spatial differences, in most cases temperature gradients remain relatively low for all relevant orders.
If there is an atomizing substance (i.e., the main tracer substance for the present study) in the column, the column is called a column oven. If there is no atomizing substance in the column, the column is called a quench oven. When combined with quenching liquor commonly used in ASIC applications (see next section), it is often called a column quenching furnace (QCF).
The column quenching furnace (QCF) is a type of ASIC device commonly used for post-column post-evaporation testing with electrons and ions, due to its small size, close approach distance between beam path of radiation with certain sample magnetization test targets mounted on it, high intensity of radiation field and uniform beam current density throughout the entire testing area. The main function of the QCF is to reduce target temperature and align target magnetization for electromagnetic and neutron transmission and reflection tests. The key parameter in QCF is the target heating rate which directly affects the energy consumption of the device.