A leakage position analyzing system includes: a first wave motion detector installed in a first pipe; a second wave motion detector installed in a second pipe connected to the first pipe; a wave motion applying device applying a wave motion to the first pipe; and a leakage position calculator calculating a fluid leakage position on the basis of the difference between the time at which the wave motion reaches the first wave motion detector and the time at which the wave motion reaches the second wave motion detector, a length La from the location in which the first wave motion detector is installed to the location of the connection with the second pipe, and a length Lb from the location in which the second wave motion detector is installed to the location of the connection with the first pipe.

A leakage position analyzing system includes: a first wave motion detector installed in a first pipe; a second wave motion detector installed in a second pipe connected to the first pipe; a wave motion applying device applying a wave motion to the first pipe; and a leakage position calculator calculating a fluid leakage position on the basis of the difference between the time at which the wave motion reaches the first wave motion detector and the time at which the wave motion reaches the second wave motion detector, a length La from the location in which the first wave motion detector is installed to the location of the connection with the second pipe, and a length Lb from the location in which the second wave motion detector is installed to the location of the connection with the first pipe.

A treatment of a possibly powdered, sintered, or deposited lattice (e.g., nickel) for heat generating applications and a way to control low energy nuclear reactions (LENR) hosted in the lattice by controlling hydride formation. The method of control and treatment involves the use of the reaction lattice, enclosed by an inert cover gas such as argon that carries hydrogen as the reactive gas in a non-flammable mixture. Hydrogen ions in the lattice are transmuted to neutrons as discussed in U.S. Patent Application Publication No. 2007/0206715 (Godes_2007)). Hydrogen moving through the lattice interacts with the newly formed neutrons generating an exothermic reaction.

A treatment of a possibly powdered, sintered, or deposited lattice (e.g., nickel) for heat generating applications and a way to control low energy nuclear reactions (LENR) hosted in the lattice by controlling hydride formation. The method of control and treatment involves the use of the reaction lattice, enclosed by an inert cover gas such as argon that carries hydrogen as the reactive gas in a non-flammable mixture. Hydrogen ions in the lattice are transmuted to neutrons as discussed in U.S. Patent Application Publication No. 2007/0206715 (Godes_2007)). Hydrogen moving through the lattice interacts with the newly formed neutrons generating an exothermic reaction.

An energy recovery system places fans inside a pipe that carries natural gas or another fluid so that as the fluid passes over them, they rotate. As the fans rotate, they cause a generator to create electricity from the rotation. The fans thereby remove energy from the natural gas so that it reaches a pressure, velocity, or temperature that it is able to be consumed at.

An energy recovery system places fans inside a pipe that carries natural gas or another fluid so that as the fluid passes over them, they rotate. As the fans rotate, they cause a generator to create electricity from the rotation. The fans thereby remove energy from the natural gas so that it reaches a pressure, velocity, or temperature that it is able to be consumed at.

The application relates to a tubular turbine device for a fluid transport network, including at least one running equipment arranged on a turbine shaft, at least one guiding equipment arranged upstream of the running equipment, and at least one generator coupled to the turbine shaft and configured to convert a mechanical energy into electrical energy, at least one cross-section adjustment equipment configured to change a cross-sectional area of the tubular turbine device that can be flowed through depending on the volume flow of the fluid flowing through the tubular turbine device.

The application relates to a tubular turbine device for a fluid transport network, including at least one running equipment arranged on a turbine shaft, at least one guiding equipment arranged upstream of the running equipment, and at least one generator coupled to the turbine shaft and configured to convert a mechanical energy into electrical energy, at least one cross-section adjustment equipment configured to change a cross-sectional area of the tubular turbine device that can be flowed through depending on the volume flow of the fluid flowing through the tubular turbine device.

System and method for gas pressure stabilization. The system comprises a pressure stabilizer which is divided into a receiving chamber and a pressure chamber by a flexible membrane, a booster device, a gas divider, and a control driver that can sense movement of the flexible membrane and control the gas divider accordingly. A pressure pilot is used to set the desired pressure in the pressure chamber. The pressure of the receiving chamber will stabilize to be the same with that of the pressure chamber regardless of the gas flow change or gas pressure change at the gas source, or the pressure fluctuation in the downstream system. The gas passing the system can eventually be recycled to a recycling system in the downstream without harming the environment.

System and method for gas pressure stabilization. The system comprises a pressure stabilizer which is divided into a receiving chamber and a pressure chamber by a flexible membrane, a booster device, a gas divider, and a control driver that can sense movement of the flexible membrane and control the gas divider accordingly. A pressure pilot is used to set the desired pressure in the pressure chamber. The pressure of the receiving chamber will stabilize to be the same with that of the pressure chamber regardless of the gas flow change or gas pressure change at the gas source, or the pressure fluctuation in the downstream system. The gas passing the system can eventually be recycled to a recycling system in the downstream without harming the environment.