A method of using a water distribution system can include measuring a property of water in the system, the system including: a multi-port service saddle mountable on a water pipe and including main and secondary ports; and a water sensing assembly including: a housing received within the main port; a generator positioned inside the housing; a sensor coupled to the secondary port and configured to be exposed to water flow within the water pipe; and a turbine coupled to a generator shaft of the generator, the turbine movable from and between a first position and a second position, the turbine in fluid communication with the water flow within the water pipe in the first position but to be in fluid communication with the water flow within the water pipe in the second position; and moving the housing to one of the first position and the second position.

A method of using a water distribution system can include measuring a property of water in the system, the system including: a multi-port service saddle mountable on a water pipe and including main and secondary ports; and a water sensing assembly including: a housing received within the main port; a generator positioned inside the housing; a sensor coupled to the secondary port and configured to be exposed to water flow within the water pipe; and a turbine coupled to a generator shaft of the generator, the turbine movable from and between a first position and a second position, the turbine in fluid communication with the water flow within the water pipe in the first position but to be in fluid communication with the water flow within the water pipe in the second position; and moving the housing to one of the first position and the second position.

The present invention provides a gas pipeline leakage monitoring system and a monitoring method, which solve the technical problem that the existing gas pipeline network leakage monitoring method has low monitoring efficiency and poor accuracy due to the presence of interference signals. In the present invention, the gas pipeline leakage monitoring system is provided with a pressure regulating apparatus, and further provided with a control apparatus, a front end and a rear end of the pressure regulating apparatus each are provided with a signal collecting apparatus, the signal collecting apparatus is for collecting signals at the front end and the rear end of the pressure regulating apparatus and uploading the signals to the control apparatus, and the signal collecting apparatus is provided with a timing apparatus. Meantime, the present invention provides a gas pipeline leakage monitoring method. The present invention can be widely applied to leakage monitoring of a gas pipeline.

A booster-ejector system captures and recycles leakage fluids from a process. When a pressure differential (head) of the process is above a threshold value, an ejector system uses motive fluid from a process high-pressure (HP) region to entrain and compress the leakage fluid, and direct it to a low pressure (LP) region. When the head is below the threshold value, a controller reconfigures a plumbing system and activates a leakage pump to pump the leakage fluid to the LP region. The system can include only one ejector, or a plurality thereof, which can be coupled such that the diffuser output of each ejector is directed to the suction input of the next ejector. At least one of the ejectors can include an exchangeable throat, which can impart a rotational component to the fluid. The HP and LP regions can be the output and input, respectively, of a compressor.

A petroleum pipeline safety system for preventing contamination of an environmentally sensitive area close to a pipeline is provided. The system includes a first portion of the pipeline including an upstream portion of the pipeline supplying a flow of fluid material and a flow restriction downstream of the first portion of the pipeline. The system further includes a second portion of the pipeline downstream of the flow restriction, receiving the flow of fluid material from the first portion and conveying the flow of fluid material through the environmentally sensitive area to a downstream portion of the pipeline. The flow restriction is configured to create a lower pipeline internal pressure within the second portion as compared to a pipeline internal pressure within the first portion. The system further includes a third portion of the pipeline downstream of the environmentally sensitive area and including the downstream portion of the pipeline.

A petroleum pipeline safety system for preventing contamination of an environmentally sensitive area close to a pipeline is provided. The system includes a first portion of the pipeline including an upstream portion of the pipeline supplying a flow of fluid material and a flow restriction downstream of the first portion of the pipeline. The system further includes a second portion of the pipeline downstream of the flow restriction, receiving the flow of fluid material from the first portion and conveying the flow of fluid material through the environmentally sensitive area to a downstream portion of the pipeline. The flow restriction is configured to create a lower pipeline internal pressure within the second portion as compared to a pipeline internal pressure within the first portion. The system further includes a third portion of the pipeline downstream of the environmentally sensitive area and including the downstream portion of the pipeline.

System and methods for analyzing a multiphase production fluid, calculating production fluid phase flow rates, and calculating an oil/gas and oil/gas/water volume fractions of the multiphase production fluid, are provided. Contemplated systems and method may utilize fluidic piping, a production fluid supply valve, a fluidic separation chamber, an inert gas exhaust valve, a separation chamber pressure sensor, a fluidic separation detector, and a fluidic supply and analysis unit.

System and methods for analyzing a multiphase production fluid, calculating production fluid phase flow rates, and calculating an oil/gas and oil/gas/water volume fractions of the multiphase production fluid, are provided. Contemplated systems and method may utilize fluidic piping, a production fluid supply valve, a fluidic separation chamber, an inert gas exhaust valve, a separation chamber pressure sensor, a fluidic separation detector, and a fluidic supply and analysis unit.

System and methods for analyzing a multiphase production fluid include a fluidic supply and analysis unit configured to transition the fluidic separation chamber to a static state after a complete gaseous phase column and a complete oil phase column are formed within the fluidic separation chamber; communicate with the fluidic separation detector to measure the absolute or relative sizes of the complete gaseous phase column and the complete oil phase column; and calculate an oil/gas volume fraction as a function of the measured sizes of the gaseous phase and oil phase columns in the fluidic separation chamber.

System and methods for analyzing a multiphase production fluid include a fluidic supply and analysis unit configured to transition the fluidic separation chamber to a static state after a complete gaseous phase column and a complete oil phase column are formed within the fluidic separation chamber; communicate with the fluidic separation detector to measure the absolute or relative sizes of the complete gaseous phase column and the complete oil phase column; and calculate an oil/gas volume fraction as a function of the measured sizes of the gaseous phase and oil phase columns in the fluidic separation chamber.