The
air in the circulating system of the air conditioning system is dissolved in
varying degrees. The solubility of air varies with the temperature and pressure
of water. The higher the temperature, the smaller the solubility; the greater
the pressure, the higher the solubility. With the constant change of
temperature and pressure in the pipeline, the dissolved air in the water also
precipitates from time to time and then dissolves. When the air is released
from the water, it begins to converge into tiny bubbles, which gradually
accumulate into larger bubbles and forms air bags. Bubbles and air bags in the
pipeline are harmful to the system, such as it will affect the heat exchange
efficiency, it will form noise; cavitation on pipe fittings, increase the power
loss of the pipeline and so on.
Aone-Best
MBS02/05/07 Micro Bubble Separator can effectively collect all kinds of tiny
bubbles in water, automatically guide them to the top of the valve body, and
discharge them from the system by automatic exhaust structure. Because it`s
working principle is to absorb micro-bubbles by internal structure, the smaller
the flow velocity in the valve body, the better the removal effect of
micro-bubbles.
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Feelin’ the Flow: Project Dalton Brings Simulation Insights to Pipe Flow Design
Project Dalton is an innovative application designed to empower engineering professionals by enabling real-time fluid flow analysis during the early stages of design. Whether it's a nation’s oil supply system or a residential building’s fire protection network, the efficient transport of liquids and gases through complex piping systems is essential across various industries.
The primary challenge for engineers lies in balancing performance, cost, and design constraints while ensuring the system meets all operational requirements. However, evaluating the effectiveness of a design typically requires time-consuming simulations that come later in the development cycle. With Project Dalton, this process becomes more dynamic and responsive.
Launched through Autodesk Labs, Dalton offers a streamlined approach for design engineers to apply fluid analysis directly within their modeling software—either as a standalone tool or integrated into platforms like AutoCAD Plant 3D and Revit MEP. This integration allows users to import standard PCF files and automatically extract key geometric data such as pipe dimensions, elevation, and layout.
From there, the user can easily define additional parameters like material properties, component specifications, and boundary conditions through intuitive input windows. The application also features a customizable library of common fluids, gases, and pipe materials, along with tools for generating pump or fan curves based on minimal input data.
Visualization tools help users understand the impact of their changes in real time, making it easier to assess how modifications affect flow direction, pressure distribution, and overall system performance. Once the model is set up, engineers can run simulations to calculate critical metrics such as pressure, flow rate, and temperature.
One of the standout features of Dalton is its ability to quickly provide feedback, allowing engineers to iterate and refine their designs efficiently. After completing the analysis, results can be exported into CSV format, and configurations can be saved for future reference.
By integrating fluid dynamics analysis into the early design phase, Project Dalton not only enhances decision-making but also reduces the need for costly redesigns later on. For more information, visit [http://labs.autodesk.com/technologies/dalton](http://labs.autodesk.com/technologies/dalton).