We offer the widest product range of low-flow (mass) flow meters and controllers on the market. Numerous styles of both standard and bespoke instruments can be offered for applications in laboratory, machinery, industry and hazardous areas.
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Bronkhorst instruments are used for numerous applications in many different markets. In this section you will find an overview of the main markets for our equipment, illustrated with some typical examples of applications.
Are you looking for technical documentation, are you interested to learn more about the measuring principles of Bronkhorst products, or you do want to get in contact with a Bronkhorst Service Engineer? This section will guide you to the relevant service & support topics.
Bronkhorst High-Tech BV the leaders in Mass Flow Meter / Mass Flow Controller technology for gases and liquids, Pressure Controllers and Evaporation Systems.
As working as a field service engineer for many years now at the company Bronkhorst, I have seen a lot installations in the field and I often get questions regarding the influence of the pipe length on the performance of a mass flow meter.
In today’s blog I will try to explain why the correct choice of piping is essential for an optimal performance of your installation using thermal mass flow meters or controllers and why this has an influence on:
Deviation in the measurement data can be caused by using a too short pipe length, because the pipe length is a parameter for the gas temperature. For an optimal performance we advise to avoid excessive temperature fluctuations during commissioning and process operation as much as possible, especially in a process with thermal mass flow meters and controllers. If you use mass flow meters based on the Coriolis principle, temperature fluctuations have no influence on the measurement data, as this measurement principle has been based on measurement of real mass.
In case of a high velocity of the gas flow, the temperature of the gas can change really quickly. In general it can be said, that the higher the flow rate, the more the gas temperature will change. This can interfere with the temperature of your instruments, as the temperature of a gas will lower much faster than the temperature of the instrument itself. This can cause a deviation in your measurement data.
Therefore, for optimal performance of a thermal mass flow meter the gas temperature should be equal to the instrument temperature. Choosing the appropriate length of piping can help you here. If the piping is long enough, the gas has the ability to cool down gradually, more at the same pace as the instrument. This will help you minimize the temperature deviation.
Another effect which I encounter in the field is frozen pipes. How do frozen pipes occur?
When a cooled gas flows with a high velocity through the piping, the temperature of the piping will lower, especially when restrictions in the piping are used, such as narrowing of pipe diameter or the use of (shut-off) valves in the piping. As a result the piping will attract moisture. If the ambient temperature lowers beneath zero degrees the moisture will freeze. This can also happen within the pipe when the medium (gas) contains moisture. In this case, using a refrigeration dryer can offer you a solution to make sure the gas which is used in the process is dry, to avoid freezing as well.
The two effects discussed here are very common in all kinds of processes with high gas flow rates (>500 l/min), such as:
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