Provided is a PCV valve assembly that includes a fluidic geometry that allows for the flow of combustion fluid/gas to flow between an inlet and an outlet and switch between two modes of operation, (i) a radial or high flow mode, and (ii) a tangential or low flow mode, as dictated during the operation of the engine. At low vacuums, the fluidic equipped PCV valve assembly has been tuned to operate in the radial mode producing high flow rates due to low flow resistance. As vacuum increases, the PCV valve assembly is tuned to automatically switch modes. This may be enabled due to the shape of the fluidic geometry and the bypass channel which is adapted to vary the amount of flow between a first and a second control ports. The bypass channel allows the geometric fluidic pattern to switch between the high flow mode and the low flow mode.

Provided is a bi-directional PCV valve assembly, system and method. The bi-directional PCV valve may include a fluidic geometry that allows for a flow of fluid a high flow rate in one direction, forward flow, and a low flow rate in the opposite direction, reverse flow. The reverse flow includes a swirling flow that increases the pressure drop and reduces the flow rate to a third of the flow rate of the forward flow. The disclosed assembly produces a strong swirling flow (vortex) in the reverse direction and an efficient (low pressure drop) flow in the forward direction.

A substrate storing container includes a container main body, a lid body removably attached to a container main body opening portion and able to close the container main body opening portion, a ventilation passage which enables a substrate storing space and a space outside the container main body to communicate with each other, a gas ejecting nozzle portion having a plurality of opening portions through which a gas flowing into the ventilation passage is supplied into the substrate storing space, and a gas flow rate uniformizing unit which enables the gas to flow out through the plurality of opening portions at a uniform flow rate.

A drip emitter has a hollow body provided with first and second pools and with an inlet recess between the first and second pools. The inlet recess has inlet hole(s). The emitter is provided with an elastic band surrounding at least one of the inlet holes. The elastic band, in its closed position, is in a tight contact with the inlet hole(s). In its open position, it is expanded to open the inlet hole(s).

A fluid sterilization device includes: a flow passage tube having a first end and a second end opposite to the first end and defining a processing passage extending in an axial direction; a light source provided in a vicinity of the first end and radiating ultraviolet light from the first end toward the processing passage in the axial direction; and a housing that defines a straightening chamber encircling the first end from outside in a radial direction. The straightening chamber includes a communication port that serves as an inlet or an outlet for a fluid flowing in the processing passage, and communicates with the processing passage via a gap between the first end and an opposing member opposing the first end in the axial direction.

The invention relates to a gas inlet system for providing gas into an analytical apparatus, comprising at least a first and a second flow restriction that are arranged on a gas inlet line, a gas flow control line connected to the gas inlet line, a gas flow controller on the gas control line, and valves for controlling gas flow in the gas inlet line and the gas control line. Also provided is a method of controlling gas flow into an analytical apparatus.

A drip emitter has a hollow body provided with first and second pools and with an inlet recess between the first and second pools. The inlet recess has inlet hole(s). The emitter is provided with an elastic band surrounding at least one of the inlet holes. The elastic band, in its closed position, is in a tight contact with the inlet hole(s). In its open position, it is expanded to open the inlet hole(s).

Provided is a PCV valve assembly that includes a fluidic geometry that allows for the flow of combustion fluid/gas to flow between an inlet and an outlet and switch between two modes of operation, (i) a radial or high flow mode, and (ii) a tangential or low flow mode, as dictated during the operation of the engine. At low vacuums, the fluidic equipped PCV valve assembly has been tuned to operate in the radial mode producing high flow rates due to low flow resistance. As vacuum increases, the PCV valve assembly is tuned to automatically switch modes. This may be enabled due to the shape of the fluidic geometry and the bypass channel which is adapted to vary the amount of flow between a first and a second control ports. The bypass channel allows the geometric fluidic pattern to switch between the high flow mode and the low flow mode.

The invention relates to a filling system (1) for a container intended to store solid particles, the system (1) being arranged to cooperate with a supply device for feeding solid particles and comprising a device (5) for distributing the solid particles, which has at least one separator element (9) intended to receive and selectively distribute the solid particles toward a dispensing device (7), the separator element (9) comprising a receiving body (11) for receiving solid particles, one end of which has an axial opening (13) for continuously feeding the dispensing device (7), the dispensing device (7) comprising at least one scattering element (21) for homogeneously filling the container with solid particles, which is driven by a drive shaft passing through the axial opening (13). According to the invention, the receiving body (11) comprises a frustoconical part (11a) which has the axial opening (13) and flares away from the axial opening (13), the frustoconical part (11a) being extended by a tubular part (11b) comprising at least one radial opening (15) which is located upstream of the axial opening (13) and is arranged to direct the solid particles without encountering those exiting the axial opening (13) before arriving in the dispensing device (7) from a predetermined amount of solid particles stored in the frustoconical part (11a) of the receiving body (11) in order to guarantee a minimum flow of solid particles even in the event of variations in the flow rate of the supply device.

A drip emitter has a hollow body provided with first and second pools and with an inlet recess between the first and second pools. The inlet recess has inlet hole(s). The emitter is provided with an elastic band surrounding at least one of the inlet holes. The elastic band, in its closed position, is in a tight contact with the inlet hole(s). In its open position, it is expanded to open the inlet hole(s).