Devices and methods for handling liquids are provided. The devices and methods make use of centrifugal forces to drive liquid flow and facilitate one or more of the mixing, metering and sequencing of liquids, for example on a microfluidic device.

A system for precision liquid delivery includes a gas reservoir having a known volume. The system has a tightly load-coupled pneumatic driver (a TLCP driver) that is configured to receive input power to cause the TLCP driver to move gas into the gas reservoir to produce a gas drive pressure. A valve is configured to couple the gas reservoir with a fluid reservoir having an unknown volume. The valve is further configured to selectively isolate or pneumatically couple pressures in the gas reservoir and the fluid reservoir. A gas-fluid interface couples pressure in the fluid reservoir to pressure in a fluid path. The fluid path is configured so that the fluid drive pressure driving the liquid in the fluid path is substantially the same as the fluid reservoir pressure. The system also has a pressure sensor configured to detect pressure in the gas reservoir and/or the fluid reservoir.

A pressure-difference transmission apparatus includes a main conduit sequentially connected to a first pressurizing device, an inlet device, an outlet device and a relief device, wherein the first pressurizing device and a second pressurizing device are in communication with the main conduit to provide pressure thereto; and a communication device connected to the relief device and in communication with an external atmospheric environment, wherein the inlet device has an inlet switch and a relief switch, the inlet switch controlling whether the inlet device and the main conduit are in communication with each other, the relief switch controlling whether the relief device and the main conduit are in communication with each other, and the communication device has a communication switch for controlling whether the communication device and the relief device are in communication with each other, thereby precluding a waste of drug, energy and time during transmission of drug.

A follower plate device for sealing and evacuating a container that has a cylindrical inner contour and contains a particularly paste-like liquid. The device comprises a seal arranged on a periphery of the device and designed so as to be able to be inserted into the cylindrical inner contour of the container such that it seals around the periphery, and marking the boundary between an outer side of the device and an inner side of the device, and a line extending through from the inner side to the outer side of the follower plate device, arranged on the outer side for connecting to a line connection leading further to an evacuation pump. The follower plate device further comprises a replaceable open-pored porous component through which the line is guided.

Provided is a microreactor which can be produced at a lower cost. The microreactor has a transfer means for transferring a liquid raw material using the pressure of a gas. The microreactor has a raw material tank for storing the liquid raw material. The transfer means for transferring a liquid raw material can transfer the liquid raw material stored in the raw material tank using the pressure of a gas in the raw material tank. A pipe which connects the raw material tank and the next device is preferably provided with a small diameter portion.

Provided is a microreactor which can be produced at a lower cost. The microreactor has a transfer means for transferring a liquid raw material using the pressure of a gas. The microreactor has a raw material tank for storing the liquid raw material. The transfer means for transferring a liquid raw material can transfer the liquid raw material stored in the raw material tank using the pressure of a gas in the raw material tank. A pipe which connects the raw material tank and the next device is preferably provided with a small diameter portion.

A container for self-gassing liquids, the container comprising a receptacle and an insert arranged to seat within a neck of the receptacle, the insert being further arranged to engage and seal directly or indirectly with a connector extending across the neck of the receptacle. The insert defines a void defined by a base portion of the insert and a peripheral side wall of the insert extending within the neck of the receptacle, the insert comprising a hole in the base portion. The container further comprises a dip tube extending from a lower surface of the base portion to, or towards, the bottom of the receptacle. The dip tube defines a passageway through the base portion, or is connected and sealed to the lower side of a passageway through the insert, the passageway terminating in said void such that the hole and the passageway are in fluid communication with each other through the void. Self-gassing liquids may be safely stored and transported in the container without risk of over-pressurisation of the internal volume of the container, which may also be quickly and easily installed into a dispensing device by the end user, requiring minimal handling by the user.

A system for precision liquid delivery includes a gas reservoir having a known volume. The system has a tightly load-coupled pneumatic driver (a TLCP driver) that is configured to receive input power to cause the TLCP driver to move gas into the gas reservoir to produce a gas drive pressure. A valve is configured to couple the gas reservoir with a fluid reservoir having an unknown volume. The valve is further configured to selectively isolate or pneumatically couple pressures in the gas reservoir and the fluid reservoir. A gas-fluid interface couples pressure in the fluid reservoir to pressure in a fluid path. The fluid path is configured so that the fluid drive pressure driving the liquid in the fluid path is substantially the same as the fluid reservoir pressure. The system also has a pressure sensor configured to detect pressure in the gas reservoir and/or the fluid reservoir.

Fuel mixed in water is combusted in a reactor having an internal operating pressure and temperature greater than 3200 psi and greater than 374 C., where the combustion of the fuel is exothermic. Air and fuel are pressurized for introduction into the reactor to a pressure greater than the internal operating pressure using energy generated from the combustion of the fuel, and the pressurized air and the pressurized fuel are injected into the reactor. Pressurized water from the reactor is injected into a drive water column that is partially filled with water to increase a pressure of the drive water column, and water at a temperature less than 100 C. is injected into the reactor to replace water from the reactor that is injected into the drive water column. Pressurized water from the drive water column is used to drive a hydroelectric drive system to produce electrical power.

A submersible landfill pump system may include sensors to detect conditions inside the pump and/or well. In some embodiments, the sensors can be placed along an electrical wire within the well and provide sensor data to a user.