Disclosed herein are robust disposable alternating tangential flow (ATF) housing and diaphragm pump units and associated methods of manufacturing, testing, wetting, and using the same.

Disclosed herein are robust disposable alternating tangential flow (ATF) housing and diaphragm pump units and associated methods of manufacturing, testing, wetting, and using the same.

Provided herein are passive microfluidic pumps. The pumps can comprise a fluid inlet, an absorbent region, a resistive region fluidly connecting the fluid inlet and the absorbent region, and an evaporation barrier enclosing the resistive region, the absorbent region, or a combination thereof. The resistive region can comprise a first porous medium, and a fluidly non-conducting boundary defining a path for fluid flow through the first porous medium from the fluid inlet to the absorbent region. The absorbent region can comprise a fluidly non-conducting boundary defining a volume of a second porous medium sized to absorb a predetermined volume of fluid imbibed from the resistive region. The resistive region and the absorbent region can be configured to establish a capillary-driven fluid front advancing from the fluid inlet through the resistive region to the absorbent region when the fluid inlet is contacted with fluid.

Provided herein are passive microfluidic pumps. The pumps can comprise a fluid inlet, an absorbent region, a resistive region fluidly connecting the fluid inlet and the absorbent region, and an evaporation barrier enclosing the resistive region, the absorbent region, or a combination thereof. The resistive region can comprise a first porous medium, and a fluidly non-conducting boundary defining a path for fluid flow through the first porous medium from the fluid inlet to the absorbent region. The absorbent region can comprise a fluidly non-conducting boundary defining a volume of a second porous medium sized to absorb a predetermined volume of fluid imbibed from the resistive region. The resistive region and the absorbent region can be configured to establish a capillary-driven fluid front advancing from the fluid inlet through the resistive region to the absorbent region when the fluid inlet is contacted with fluid.

A compressor and method are provided, the compressor having elliptically-shaped combustion chambers including a first chamber having a first inlet and a first outlet, and a last chamber having an inlet and outlet. The first inlet is in communication with a low pressure plenum, the first outlet is in communication with the inlet of the last chamber, and the outlet of the last chamber is in communication with a high pressure plenum to define a flow pathway. A volume of gas is introduced into the first chamber at a first pressure. A fuel is injected into the first chamber, alternately at the foci, and ignited to advance the volume of gas along the flow pathway. A fuel is injected into the last chamber, alternately at the foci, and ignited on a schedule synchronized with ignition in the first chamber to further advance the volume of gas along the flow pathway.

A compressor and method are provided, the compressor having elliptically-shaped combustion chambers including a first chamber having a first inlet and a first outlet, and a last chamber having an inlet and outlet. The first inlet is in communication with a low pressure plenum, the first outlet is in communication with the inlet of the last chamber, and the outlet of the last chamber is in communication with a high pressure plenum to define a flow pathway. A volume of gas is introduced into the first chamber at a first pressure. A fuel is injected into the first chamber, alternately at the foci, and ignited to advance the volume of gas along the flow pathway. A fuel is injected into the last chamber, alternately at the foci, and ignited on a schedule synchronized with ignition in the first chamber to further advance the volume of gas along the flow pathway.

A jet pump assembly for facilitating a jet pump to be dissembled and serviced in the field includes a jet pump that is fluidly coupled to a fluid pump for pumping a fluid into a petroleum well at a given pressure. The jet pump includes a nozzle housing, a mixing tube, a diffuser, a crossover body and an outer sleeve. The diffuser threadably engages the crossover body, the outer sleeve threadably engages each of the nozzle housing and the crossover body for assembling the jet pump. In this way the jet pump can be dissembled and serviced, in the field, without special tools or training.

A jet pump assembly for facilitating a jet pump to be dissembled and serviced in the field includes a jet pump that is fluidly coupled to a fluid pump for pumping a fluid into a petroleum well at a given pressure. The jet pump includes a nozzle housing, a mixing tube, a diffuser, a crossover body and an outer sleeve. The diffuser threadably engages the crossover body, the outer sleeve threadably engages each of the nozzle housing and the crossover body for assembling the jet pump. In this way the jet pump can be dissembled and serviced, in the field, without special tools or training.

Provided herein are passive microfluidic pumps. The pumps can comprise a fluid inlet, an absorbent region, a resistive region fluidly connecting the fluid inlet and the absorbent region, and an evaporation barrier enclosing the resistive region, the absorbent region, or a combination thereof. The resistive region can comprise a first porous medium, and a fluidly non-conducting boundary defining a path for fluid flow through the first porous medium from the fluid inlet to the absorbent region. The absorbent region can comprise a fluidly non-conducting boundary defining a volume of a second porous medium sized to absorb a predetermined volume of fluid imbibed from the resistive region. The resistive region and the absorbent region can be configured to establish a capillary-driven fluid front advancing from the fluid inlet through the resistive region to the absorbent region when the fluid inlet is contacted with fluid.

Provided herein are passive microfluidic pumps. The pumps can comprise a fluid inlet, an absorbent region, a resistive region fluidly connecting the fluid inlet and the absorbent region, and an evaporation barrier enclosing the resistive region, the absorbent region, or a combination thereof. The resistive region can comprise a first porous medium, and a fluidly non-conducting boundary defining a path for fluid flow through the first porous medium from the fluid inlet to the absorbent region. The absorbent region can comprise a fluidly non-conducting boundary defining a volume of a second porous medium sized to absorb a predetermined volume of fluid imbibed from the resistive region. The resistive region and the absorbent region can be configured to establish a capillary-driven fluid front advancing from the fluid inlet through the resistive region to the absorbent region when the fluid inlet is contacted with fluid.