Our deaerators

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What is deaeration?

Enhancing the lifespan and design efficiency of steam-generating boilers involves mitigating internal corrosion. This goal is accomplished by minimizing the dissolved oxygen in the water-steam cycle, a process known as deaeration. Deaeration, in general, refers to removing dissolved air from a gas or liquid. Thermal deaeration is presently the predominant method for deaeration in industrial boilers, surpassing chemical techniques due to its effectiveness in regulation, efficiency, and cost optimization.

For thermal deaeration, the water saturated with oxygen must be brought into contact with steam. The more water surface contacts the steam, the more complete the deaeration process will be. In an industrial or utility water-steam-cycle behind a boiler this is done in a deaerator vessel or feedwater tank.

While the overall design of deaerators has remained relatively consistent for the past few decades, their applications have significantly expanded due to the adoption of energy-efficient technologies and new energy sources.

deaeration
The tray-type deaerator

The spray-type deaerator

The operating principle of the spray type deaerator is schematically shown on the picture.

Cold condensate enters via water inlet into the spray section, at its heart a highly effective atomizing nozzle. The nozzle creates several layers of spray films on top of each other, which hit a circular baffle plate and then drop down into the feedwater tank.

The circular spray contains very fine drops of water. In a matter of a fraction of a second, these small droplets are heated up in the air around the spray nozzle by steam entering the spray area from below.

The spray-type deaerator

Due to the high efficiency of the sprayer, 95% of the deaeration of the water takes place in the first milliseconds around the spray nozzle. The water is heated and almost completely oxygen-free already, when it hits the circular splash plate.

Inside the water volume, the second phase of deaeration, the polishing phase, starts. The 5% remaining solved oxygen is driven out by the injected steam passing through the water to the surface.

The steam travels to the spray area, condenses for a large part in the water spray, and then leaves in a minimal amount only with the non-condensable gasses via two vents left and right of the water inlet.

The tray-type deaerator

The operating principle of the tray type deaerator is schematically shown on the pictures.

Cold condensate enters via water inlet into the dome section, via several small sprayers. From there, the water is collected by the first tray, which is partly perforated and lets the water trickle down to the next tray.

Between the trays, the steam comes into contact with the water, counter-flowing from below to the top of the tank.

three-tray-fixed
three-tray-fixed

The water leaves the top tank and flows down to the storage tank via its opening in the bottom. The storage tank can contain a steam distribution under water, similar to the spray-type deaerator, to polish the result.

three-tray-fixed
three-tray-fixed

The US version of the Tray-type

With US EPCs and power plant operators, a variant of the tray-type system above is commonplace, which uses a horizontal top tank with several boxes of stainless steel tray stacks inside, through which the water cascades down, and the steam comes into contact with the dripping water counter-flowing.

three-tray-fixed

Which Information do we need from you to calculate an offer?

Ideally, we would get the following 6 pieces of information from you:

General design data:

  1. Design code (ASME / PED / Other)

  2. Design pressure (barg)

  3. Operating pressure (bara) or feedwater outlet temperature

  4. Required performance / oxygen content in feetwater (e.g. 7 ppb / 10 ppb / 20 ppb)

  5. Required storage capacity (either in minutes of hold-up time, or in m3), storage capacity is the water volume between normal water level (NWL) and low water level (LWL)

three-tray-fixed

6. Normal / minimal / maximal operating case:

  • Incoming condensate flow (t/h)

  • Incoming condensate temperature (deg. C)

  • If applicable: Make-up water flow and temperature

  • Steam available: max flow, temperature, pressure

For a good calculation we need three cases, nominal, minimal and maximal loads. If you have only one nominal or max case for a budget, we can also do a calculation based only on one case and assume the rest. If you have any additional operating cases available, for example a turbine bypass case or a startup case, please also provide those.

Production examples

If you need a deaerator for your system, please contact us. We find the ideally fitting design with you, and offer accordingly.