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.
Customer satisfaction, innovation and quality of product and service have been the cornerstones of Bronkhorst's success. Based on our experience, innovation and sense of responsibility, a relationship with Bronkhorst assures Performance for Life.
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 UK is leader in Mass Flow Meter / Mass Flow Controller technology for gases and liquids, Pressure Controllers and Evaporation Systems.
First you need to know what aspects you should consider when selecting a flow meter. Before you start to select the right flow meter, it is necessary to know what the purpose is of your application. It can be gas, liquid or vapour instrument.
But, let’s start by explaining a bit more about what flow meters are, how they work, what they are used for and the criteria to select the best flow meter for the application.
A flow meter is an instrument that measures a mass or volumetric flow rate of a gas or liquid. You might have come across a variety of terms when referring to a flow meter, such as flow sensor, mass flow meter, mass flow controller, flow regulator etc.
The purpose of a flow meter is basically to measure the flow of gas or liquid between two points in a process. Sometimes it is neccessary to control or regulate the flow. This is done by combining a flow meter with a valve, creating a flow controller. In this case, besides measuring a flow, you can also control it to change the flow rate. The output can help you better understand your process to make decisions regarding product quality, speed of process and cost reduction.
There are two basic types of fluid measurement – mass and volume flow measurement. The volumetric flow measurement is temperature and pressure dependent especially for gas and will be shown in units of volume such as ml/min or m3/h. When measuring mass flow, you see units of mass such as kg/h or g/min. Alternatively, because gas is compressible, it is more convenient to express mass flow as standardised volumes, e.g. mls/min or m3n/h. Therefore, you can either choose a mass flow meter or a volumetric flow meter for your application.
Besides these two types of measurement, there are different measuring principles that all have their specific advantages and disadvantages:
Some flow meters are developed for gas, some specially for liquid. There are also flow meters available on the market that are independent of the fluid properties and can therefore handle both gas and liquids.
You can find a glossary page on our website, in which you will find many terms and abbreviations that are common in the field of flow measurement.
Flow meters are used in a wide variety of applications; here are some examples:
In this paragraph, we will discuss some of the key factors involved into choosing a flow meter. In doing so, we consider the differences between various measurement principles. Read below what to consider when selecting a flow meter. There is a big difference between lab and industrial applications but most of the considerations are required for both application fields.
The flow rate is usually the most important specification to consider when selecting a flow meter. Fluid quantity can be displayed in volume, standardised volume and true mass units. The flow rate is the quantity of fluid per unit time flowing through a measuring device.
Check out the blog to find out why it is important to know what reference conditions you are working with. A supplier usually indicates the minimum and maximum full-scale range of a product series. This should meet your process requirements.
Chemical and physical properties of the medium can influence the material of the flow meter and therefore the working of the instrument. Commonly, the following wetted parts (parts that are exposed to or in direct contact with the medium) may be offered:
When selecting a flow meter, it is important to know whether you need a low pressure drop or not. The pressure drop is defined as the difference between the inlet and outlet pressure. In addition, flow meters have a maximum operating pressure. If you have a high-pressure application, you need to take this pressure rating into consideration.
In the case of mass flow control, the inlet pressure (P1) and outlet pressure (P2) are required for the selection and dimensioning of the most appropriate control valve.
The temperature of your fluid and the instrument’s environment are the next factors to check.
Variations in fluid temperature may affect the accuracy of your measurement. In the case of temperature fluctuations, it could be interesting to select a flow meter with temperature compensation (e.g. the EL-FLOW Prestige flow meters).
Too high or too low environment temperatures may also harm the electronic components of your flow meter during operation or storage. When you use a flow meter in a furnace or burner application, or in areas with very low temperatures, it is important to check whether the instrument can withstand these extreme temperatures. So, check the temperature specifications as provided by the supplier before selecting your flow meter.
When selecting your flow meter, you must consider where you will install it, whether indoors, outdoors, in a laboratory or for a particular industry. For laboratories, other specifications apply than for the oil and gas industry.
When selecting your flow meter, you need to consider what is important in your process. What do you want to achieve?
The specifications of the flow meter must be considered when selecting a flow meter. Accuracy and repeatability are important specs to look at.
Accuracy is how close the measurement is to the true value. For flow meters, the measured deviations are often visualised on a calibration certificate. This is expressed as a percentage, e.g., ±1%. Not all flow meters offer the same accuracy, but not all applications require the highest possible accuracy. Nevertheless, absolute accuracy is important in quantitative research and development or catalytic applications.
Repeatability is producing the same outcome given the same conditions. In other words, a flow meter should produce the same readings when operated under the same variables and conditions. This, too, is expressed as a ± percentage. This is particularly important for burner applications, for example.
Sometimes it makes sense to select a flow meter that can be used in multiple applications. For example, when you need an instrument in a research project and you know that other projects will follow in the future, but you have no idea what fluids are used then. In such case, it can be beneficial to select a flow meter that is fluid independent and has a wide flow range as well.
When you install a flow meter you want the best performance right away. Check out our top 10 tips for installing your flow meter.
Thermal mass flow meters are used to measure mass flow of low gas flow. A mass flow controller is a flow meter combined with a control valve.
What is the difference between laminar flow and turbulent flow? 3 Tips how to minimise the effects of turbulent flow on your flow meters.
Do you need help selecting a flow meter? We can help you.