Bitcontrol is the developer of AQUA DESIGNER, a software tool used for the planning of wastewater treatment plant (WWTP) processes, that range from mechanical biological systems to the treatment of sludge.
Effluent Treatment Plant Design Software
The software tool can be used for both anaerobic and aerobic sludge treatment. Additionally, it covers buffer tanks, oxygen efficiency, estimated operation costs, as well as machine and measuring lists.
AQUA DESIGNER is one of the standard design programs for activated sludge plants in Germany and worldwide. The range of tools has been extended over the last few years to all important procedures and procedural stages.
The Environmental Technologies Design Option Tool (ETDOT) is a suite of software models that provides engineers with the capability to evaluate and design systems that use granular activated carbon or ion exchange resins for the removal of contaminants, including PFAS, from drinking water and wastewater.
Even though carbon adsorption can be an effective treatment technology for removing organic compounds, such as PFAS, from water, it can be expensive or may not achieve desired removal objectives if improperly designed. Proper full-scale design of this adsorption process typically results from carefully controlled pilot-scale studies that are used to determine important design variables, such as the type of adsorbent, empty bed contact time, and bed configuration. However, these studies can be time consuming and expensive if they are not properly planned.
The information generated from the ETDOT models can be used to help design pilot treatment systems and provide a first-cut prediction of full-scale results. The information will also provide states and utilities with a better understanding of the fundamentals of carbon adsorption and what that means to the operation, performance, and costs associated with this technology.
Develop digital twins, implement new control strategies and optimise plant operations using the open and flexible software platform, WEST+, for advanced process modelling and statistical analyses.
Reduce the time and cost required to design your next water or wastewater treatment plant, leveraging collaborative design and BIM. Increase speed and flexibility with an environment that supports project teams working together online or independently offline. Get a 3D design for piping, HVAC, and mechanical and electrical equipment, with automatic clash detection, version comparison, and issue resolution.
To increase the existing flow and treatment capacity, engineers were tasked with designing the complex retrofit project and faced challenges coordinating a remote team, compounded by the limited functionality of existing outdated as-built models.
Proper wastewater treatment equipment and design are essential to ensure that the water is clean enough to be safely released back into the environment. There are many different types of wastewater treatment plants, each with its unique design. These plants use a variety of treatment equipment that include tanks, filters, and screens which all can be bought commercially with sub-surface or above-ground systems.
Understanding the local environment is crucial when designing a wastewater treatment plant. The climate, geography, and geology of the area must be taken into consideration to create a plant that is effective and efficient.
After the local environment has been taken into account, the next step is to analyze the wastewater itself. This includes testing the water for various contaminants, such as bacteria, viruses, fungi, and other microorganisms. Once these contaminants have been identified, the proper treatment processes can be designed.
Designing a wastewater treatment plant is a complex process, but it is essential to protecting our environment. By following these simple steps, you can ensure that your plant is effective and efficient.
With the Transcend Design Generator, you can quickly and easily create a three-dimensional Building Information Model (BIM) model of your wastewater treatment plan developed from calculations of different water & wastewater treatment engineering fields. Our user-friendly, engineering quality software automatically completes a process simulation, selects the proper equipment, and decides how each element is structured.
As technology advances, so does the wastewater treatment industry. There are always new and improved ways to treat wastewater. By staying up-to-date on the latest technology, you can ensure that your treatment plant is operating at its fullest potential.
Wastewater treatment plant design is a critical process that should not be taken lightly. There are many factors to consider, such as the type of wastewater, the desired outcome, and the surrounding neighborhood. By taking the time to design a well-thought-out treatment plant, you can save yourself time and money in the long run.
This paper presents a computer tool called DSC (Simulation based Controllers Design) that enables an easy design of control systems and strategies applied to wastewater treatment plants. Although the control systems are developed and evaluated by simulation, this tool aims to facilitate the direct implementation of the designed control system to the PC of the full-scale WWTP (wastewater treatment plants). The designed control system can be programmed in a dedicated control application and can be connected to either the simulation software or the SCADA of the plant. To this end, the developed DSC incorporates an OPC server (OLE for process control) which facilitates an open-standard communication protocol for different industrial process applications. The potential capabilities of the DSC tool are illustrated through the example of a full-scale application. An aeration control system applied to a nutrient removing WWTP was designed, tuned and evaluated with the DSC tool before its implementation in the full scale plant. The control parameters obtained by simulation were suitable for the full scale plant with only few modifications to improve the control performance. With the DSC tool, the control systems performance can be easily evaluated by simulation. Once developed and tuned by simulation, the control systems can be directly applied to the full-scale WWTP.
Kimley-Horn provided complete planning, design, and construction phase services to the Gainesville Wastewater Treatment Plant to assist in the improvement of the existing conventional activated sludge treatment facility.
Kimley-Horn kept the same consultative and methodical approach during the design phase, using 3D design software and sophisticated modeling to create virtual walkthroughs of the facility for review with the City. These models gave the City a more tangible view of the proposed solutions and potential impacts. Our team of engineers supported the City throughout the project as trusted advisors, providing guidance on whether to reuse, repurpose, or remove existing infrastructure to provide cost-effective water treatment solutions.
The project was constructed in two phases. The first phase included installing a new headworks structure with mechanical bar screen and new solids handling facilities with a belt filter press, repurposing an existing clarifier as an aerobic digester, and rehabilitating the administration building. Phase II of the project replaced the trickling filter process with new sequencing batch reactors. Kimley-Horn assisted during the construction phases to keep the existing plant operational until the new plant was up and running. The new plant is now producing high-quality effluent and achieving effective biological nutrient removal.
Kimley-Horn was responsible for all design, construction document preparations, permitting, SRF funding assistance, bid administration, and construction administration for the rehabilitation and expansion of an existing 1.9-MGD wastewater treatment facility in Lake Wales, Florida.
DWG ASSOCIATES not only understands high-purity oxygen (HPO) wastewater technology, we can model it and we can simulate it. Our simulators are accurate, realistic, and specifically developed to mimic HPO wastewater treatment plants. That means a covered, staged aeration basin where the feed gas and mixed liquor flow concurrently through the reactor.
Drag, drop and connect unit operations on a flowsheet, then configure each unit operation to tailor your concept design or begin with typical defaults preloaded into each operation. Configured plants can be matched with any user scenario & shared with other users in your organisation.
Percent Recovery is the amount of water that is being 'recovered' as good permeate water. Another way to think of Percent Recovery is the amount of water that is not sent to drain as concentrate, but rather collected as permeate or product water. The higher the recovery % means that you are sending less water to drain as concentrate and saving more permeate water. However, if the recovery % is too high for the RO design then it can lead to larger problems due to scaling and fouling. The % Recovery for an RO system is established with the help of design software taking into consideration numerous factors such as feed water chemistry and RO pre-treatment before the RO system. Therefore, the proper % Recovery at which an RO should operate at depends on what it was designed for. By calculating the % Recovery you can quickly determine if the system is operating outside of the intended design. The calculation for % Recovery is below: 2ff7e9595c
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