User:FigJam164/Lean Air
Lean Air is air with an oxygen content lower than the oxygen content of the normal breathing air. The generic term for this is synthetic air which can refer to gas mixtures with a lower but also a higher content of oxygen. Synthetic air is used e.g. used for gas analyzers as zero gas[1][2] or operating gas for the detection of nitrogen oxides. In large scaled chemical processes the gas mixture is used in significantly larger quantities and there has an impact on product quality. The demands for quantity, quality, security and availability are individually graded and are defined by company-specific needs.
Definition[edit]
Lean air is artificially produced "air" with a lower oxygen content. The oxygen content of 20.95 vol .-% in air shall be reduced (lean) to a lower proportion (e.g. 4–10 Vol.-% Oxygen in the gas mixture). For this purpose, gases are mixed: either compressed air or oxygen with nitrogen, so that lean air is generated with a desired oxygen concentration.
Lean air can be filled in gas bottles or bundles (storage banks) from manufacturers of technical gases [1] [2] [3]. When larger quantities are required, companies usually operate their own systems for generating lean air [4]. Plants for the production of such gas mixtures are called gas mixers, specific lean air units.
Usage[edit]
Lean air is often required in processes for the supply of solvent boilers and reactors, e.g. in the production of synthetic resins during Polymerization.[5] In these processes, heat is added and combustible gases escape from the product. Thus, the three required factors of the combustion triangle (combustible substance, oxygen, ignition energy) would coincide spatially and temporally if produced under normal breathing air, which could lead to an explosion or deflagration, with consequent serious accidents. Overlaying the product with a pure nitrogen atmosphere during the manufacturing process prevents explosion or deflagration. However, parts of the chemical reaction require oxygen. Thus lean air is used for this purpose, with an oxygen content that remains safely below a defined limit concentration so that the lower explosion limit is not exceeded and accidents are prevented.
Due to the regular use in potentially explosive areas, compliance with the oxygen content specified for the lean air, i.e. both for the quality of the production process (desired chemical reaction) and for safety-related matters (combustion triangle), is essential.
Requirements for the generation of lean air[edit]
From the usage described it is obvious that the influences quality, safety and availability are important for the process plant operator[3]. In relation to lean air systems, this means:
- Exact observance of the defined oxygen concentration in the lean air-gas mixture for the production of a constant product quality (quality)
- Safe shutdown if a specified oxygen concentration is exceeded so that there is no risk of explosion (safety)
- Using backup solutions or a bypass with pure nitrogen, ensuring the availability of the production system (availability)
The choice of the system technology itself has an influence on the gas mixture quality and thus on the product quality.
Quality[edit]
As an additional measure to monitor the correct gas mixture quality, a gas analyzer can be provided that continuously monitors the oxygen concentration. The measured oxygen value can be displayed and transferred to a higher-level process control system via an online connection. If the limit value is exceeded, a change in the quality of the gas mixture (in the case of automatic, dynamic lean air systems) can be initiated, and a shutdown or a switchover to a possibly existing bypass can be initiated.
Safety[edit]
The safe compliance with a defined oxygen concentration in the lean air influences the safety of the supplied process plant. Functional safety can be additionally increased by using a Safety Integrity Level analysis (SIL analysis). A SIL or security level is a security requirement level in accordance with the standard IEC 61508 / IEC 61511. The monitoring system used for this (usually consisting of a gas analyzer, shutdown, blow-off line solenoid valve) is assessed jointly with regard to its reliability by this SIL analysis. This further reduces the risk of potential malfunctions.
Availability[edit]
To ensure the availability of a professionally designed lean air system, at least the following measures are common[4]:
- Gas filter on the gas inlet side, to avoid impairment of the functioning of the fittings by particle entry,
- Pressure control of compressed air and nitrogen to the same mixed pressure, so that Avogadro's law of the ideal gas applies, i.e. the density of the gases is proportional to the molar mass at the same pressure and temperature,
- Interconnection of the constant pressure regulators in the gas inlet lines so that the impermissible enrichment of admixing gas is excluded at any time. Additional locking via the gas analysis so that a redundant safety lock is created.
- Volume flow measurement (temperature and pressure compensated),
- Use of gas non-return valves in each individual gas line to prevent decanting,
- Enabling continuous or discontinuous gas mixture consumption through design measures,
- Ensuring autonomous plant operation, even in the event of an eventual fault in a higher-level process control system or in the communication with it.
Weblinks[edit]
- ^ "Synthetic Air". Retrieved 2020-02-19.
{{cite web}}: CS1 maint: url-status (link) - ^ "Air -Delivering a wide range of synthetic and compressed air cylinder options to meet your varied needs". Retrieved 2020-02-19.
{{cite web}}: CS1 maint: url-status (link) - ^ Hanf, Alexander (2017-01-15). "Lean Air Units" (PDF). Retrieved 2020-02-19.
{{cite web}}: CS1 maint: url-status (link) - ^ Hanf, Alexander. "Lean Air Units" (PDF). Retrieved 2020-02-19.
{{cite web}}: CS1 maint: url-status (link)
Category:Gas technologies Category:Process technology Category:Breathing gases Category:Industrial gases