A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
HYDEL POWER GENERATION FROM MULTI STOREY BUILDING SEWERAGE
"HYDEL POWER GENERATION FROM MULTI STOREY BUILDING SEWERAGE" Exemplary aspects of the present disclosure are directed towards the " HYDEL POWER GENERATION FROM MULTI STOREY BUILDING SEWERAGE" consisting of Waste Water Collection Arrangement (WWCA) 001, Water-Level Monitoring Device (WLMD) 100, and an Electricity-Generating Unit (EGU) 200. Waster-Water Collection Arrangement (WWCA) 001 comprises Plurality of sub-storage system 002 collecting sewerage/ waste-water, Filter arrangement 003 and Storage-Tank 004. Water Level Monitoring Device (WLMD) 100 encompassing Microcontroller 103, Water-level sensors 103a, and Outlet-Value control 103b. Electricity Generating Unit (EGU) 200 comprises Horizontal-Turbine 201, an Electrical Generator 202, and an Inlet-Arrangement 203 and Outlet-arrangement 204. Microcontroller 101a executes the relevant machine learning algorithm in coordination with Water-level sensors 103a identifies the exact amount of water in the Storage-tank 004 and sub-storage tanks 002. Based on the prediction system, microcontroller 103 opens the Outlet-Value control 103b, thereby releasing the water through Inlet-Arrangement 203 on to Horizontal-Turbine 201 to rotate the Electrical-Generator 202. The electricity produced is stored/utilized for the building lighting-system. Acquire Water level in sub-storage tanks 002 and 004 using sensors 103a Execute Relevent machine learning algorithm on water level sensor 103a data and accertain maximum waste-water flow rate and there by maximum power 302 that can be generated. Execute Relevent machine learning algorithm on water level sensor 103a data 303 and accertain the optimal timings to which the Outlet-Value control 103b of enneerned tankscn he nnernt 7 Either the predicted optimal timing or power level reaches threshold value 304 then turn on the Outlet-Value control 103b of concerned tanks. 305 Measure the energy produced through the Electricity Generating Unit (EGU) Intimate the user about the predicted and actual energy generated 307 Close the Outlet-Value control 103b either optimal timing or the water level reaches threshold value, and intimate the user FIG3 300 Process Executed Water-Level Monitoring Device (WLMD)
HYDEL POWER GENERATION FROM MULTI STOREY BUILDING SEWERAGE
"HYDEL POWER GENERATION FROM MULTI STOREY BUILDING SEWERAGE" Exemplary aspects of the present disclosure are directed towards the " HYDEL POWER GENERATION FROM MULTI STOREY BUILDING SEWERAGE" consisting of Waste Water Collection Arrangement (WWCA) 001, Water-Level Monitoring Device (WLMD) 100, and an Electricity-Generating Unit (EGU) 200. Waster-Water Collection Arrangement (WWCA) 001 comprises Plurality of sub-storage system 002 collecting sewerage/ waste-water, Filter arrangement 003 and Storage-Tank 004. Water Level Monitoring Device (WLMD) 100 encompassing Microcontroller 103, Water-level sensors 103a, and Outlet-Value control 103b. Electricity Generating Unit (EGU) 200 comprises Horizontal-Turbine 201, an Electrical Generator 202, and an Inlet-Arrangement 203 and Outlet-arrangement 204. Microcontroller 101a executes the relevant machine learning algorithm in coordination with Water-level sensors 103a identifies the exact amount of water in the Storage-tank 004 and sub-storage tanks 002. Based on the prediction system, microcontroller 103 opens the Outlet-Value control 103b, thereby releasing the water through Inlet-Arrangement 203 on to Horizontal-Turbine 201 to rotate the Electrical-Generator 202. The electricity produced is stored/utilized for the building lighting-system. Acquire Water level in sub-storage tanks 002 and 004 using sensors 103a Execute Relevent machine learning algorithm on water level sensor 103a data and accertain maximum waste-water flow rate and there by maximum power 302 that can be generated. Execute Relevent machine learning algorithm on water level sensor 103a data 303 and accertain the optimal timings to which the Outlet-Value control 103b of enneerned tankscn he nnernt 7 Either the predicted optimal timing or power level reaches threshold value 304 then turn on the Outlet-Value control 103b of concerned tanks. 305 Measure the energy produced through the Electricity Generating Unit (EGU) Intimate the user about the predicted and actual energy generated 307 Close the Outlet-Value control 103b either optimal timing or the water level reaches threshold value, and intimate the user FIG3 300 Process Executed Water-Level Monitoring Device (WLMD)
HYDEL POWER GENERATION FROM MULTI STOREY BUILDING SEWERAGE
MOHAMMED ARSHAD (author) / KHAN AMER ALI (author) / MAAZ AHMED (author) / J DHANRAJ PAMAR (author) / G SREENIVASULU REDDY (author) / K SARUPYA SANTHOSH (author) / BIREDDY SRINIVASA REDDY (author) / JAVED SYED (author) / MIRZANA ISHRAT MEERA (author) / NBV LAKSHMI KUMARI (author)
2021-06-03
Patent
Electronic Resource
English
IPC:
E03F
SEWERS
,
Abwasserkanäle
/
G05B
Steuer- oder Regelsysteme allgemein
,
CONTROL OR REGULATING SYSTEMS IN GENERAL
/
H02J
CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER
,
Schaltungsanordnungen oder Systeme für die Abgabe oder Verteilung elektrischer Leistung
/
H02K
Dynamoelektrische Maschinen
,
DYNAMO-ELECTRIC MACHINES
Structural design of hydel power station
| Engineering Index Backfile | 1964
Malana Hydel Power Tunnel-Geotechnical Design Appraisal
| British Library Conference Proceedings | 1999
| Engineering Index Backfile | 1967