Pond-In-Pond: An alternative system for wastewater treatment for reuse

Adhikari, Kushal; Fedler, Clifford B.

doi:10.1016/j.jece.2019.103523

Cited by 20 publications

(16 citation statements)

References 37 publications

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“…Ponds used for treating municipal wastewater range from aerobic to facultative to anaerobic [28] and several procedures have been developed to design these various types of ponds [29,30,31,32,33,34,35]. Numerous studies [16,36,37] have been done on different pond systems and existing design criteria and their limitations. Many of these pond designs have been in existence for decades, yet there is a lack of design specifications with respect to pond performance.…”

Section: Wastewater Treatment Systemsmentioning

confidence: 99%

“…Many of these pond designs have been in existence for decades, yet there is a lack of design specifications with respect to pond performance. Also, there exist strong contradictory viewpoints regarding pond dimensions as they relate to pond performance [16]. This clearly illustrates that existing knowledge on the design of ponds is inadequate and that more research is required to develop an effective pond design procedure.…”

Section: Wastewater Treatment Systemsmentioning

confidence: 99%

“…One of the potentially viable and sustainable treatment technologies could be a simple, low-cost, and low-maintenance natural treatment system known as Pond-In-Pond (PIP). The PIP is a treatment technology in which the two types of ponds--anaerobic and aerobic--are combined into a single pond [16,28,38]. The PIP system combines the functionality of two different ponds and provides more efficient conversion of wastewater, including high-strength waste, to end products through the synergistic relationships of the various microorganisms' present.…”

Section: Wastewater Treatment Systemsmentioning

confidence: 99%

“…For land application systems, the effluent quality is less stringent, usually 2-3 times higher than that required for stream discharge [15,16] thus, the need for expensive advanced wastewater treatment facilities can be diminished through reuse. Considering the reduced cost in treatment plant construction for reuse systems, billions more in capital costs could be saved in the future as the population continues to grow.…”

Section: Introductionmentioning

confidence: 99%

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2-D modeling to understand the design configuration and flow dynamics of Pond-In-Pond (PIP) wastewater treatment system for reuse

Adhikari

Fedler

Asadi

2021

Process Safety and Environmental Protection

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Water reuse for irrigation is increasingly recognized as an essential and economical strategy in areas with water scarcity. A simple, low cost, low-maintenance, and highly efficient Pond-In-Pond (PIP) treatment system can be used for wastewater reuse. PIP is a treatment technology in which two types of ponds --anaerobic and aerobic --are combined into a single pond and consists of a deeper inner section entirely submerged within the outer pond. Previous studies on PIPs and PIP-like systems have reinforced the potential for reuse through promising performance results with BOD removal over 80% and a reduction in land area requirements by approximately 40%. Yet, no prior efforts have been made to understand the performance mechanism of such systems. This study makes use of two, 2-D modeling tools in developing a fundamental understanding of PIP flow dynamics and the expected performance. The modeling results showed that the PIP configuration offers improved flow-diversion along with reduced flow velocity. Additionally, the PIP retained approximately 17% more (p<0.05) particles than the traditional pond with most of the particles concentrated within the inner pond. Lower velocity and the higher solids retention in the PIP thus allowed for better treatment performance compared to traditional ponds.The findings from this study can be used as preliminary data for future in-depth investigations of the PIP system leading toward effective and optimal designs. This will help address the major societal concern of water scarcity with low-cost and effective wastewater treatment.

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Section: Wastewater Treatment Systemsmentioning

confidence: 99%

Section: Wastewater Treatment Systemsmentioning

confidence: 99%

Section: Wastewater Treatment Systemsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

2-D modeling to understand the design configuration and flow dynamics of Pond-In-Pond (PIP) wastewater treatment system for reuse

Adhikari

Fedler

Asadi

2021

Process Safety and Environmental Protection

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“…Generally speaking, fins are usually used in the solar stills in order to reduce the water's preheating time and achieve positive water and also to attain cover temperature of inner glass during morning hours for increase in the distillate output. Adhikari et al (2020) [2] introduced many approaches of ponds design and suggested use of Pond-In-Pond (PIP) VOL.7, ISSUE 3, MARCH 2021 approach as a more apt design for the purpose of reusing, PIP is mostly the integration of two sorts of ponds :-aerobic and anaerobic. Anagnostopoulos et al (2020) [3] Developed a CFD simulated model in its work in order to obtain an all over versatile which is practically applicable to most practical scenario.…”

Section: Literature Reviewmentioning

confidence: 99%

Article of Review on Computational Analysis on Performance of Solar Pond using Polycrystalline Material

Rehman¹,

Arya²,

Vishwakarma³

2021

IJOSCIENCE

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The Solar pond is a pool of salt water stratified into 3 different layers, when radiations from the sun heats up the pond this heat energy gets stored in the lower most layers, thus making it as a heat source. Latent heat thermal energy storage is constantly an attractive method to store thermal energy due to because of its capacity to give high energy storage density and it also has a property to store heat at almost constant temperatures equivalent to the phase transition temperature of phase change materials (PCM). The aim of the thesis is to develop a CFD-based simulation analysis model of solar pond to analyze the double-diffusive nature of temperature and the saline concentration distributions, also to form a stable three-layer system of energy storage using computational fluid dynamics. The main objective of this study was to design solar pond modal with three layers in it and also to explore the effects of addition of material with high conductivity on the characteristics of heat transfer of pure PCM.

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