A control assembly can be configured for use with a pressure regulator having a valve body defining a fluid flow path. The control assembly can include a control member, a stem, and a lever, and can be disposed within the pressure regulator to selectively control fluid flow. The control assembly can include a primary control member and a secondary control member, or a mechanical stop that can operate to restrict flow along the fluid flow path, including when the stem disconnects from the lever.

A back pressure regulator (“BPR”) includes a pressure housing that at least partially defines a flow chamber that the liquid flows through and the BPR has an adjustable restriction that varies with the flow rate to maintain an upstream liquid pressure. The pressure housing is contoured to distribute the liquid flow to provide radial flow into the adjustable restriction from circumferentially about the adjustable restriction. The pressure housing includes ramped and curved side passages that guide the flow and ridges that divide the flow and prevent internal collisions between the flow. A flow deflector extends into the chamber outlet to prevent the radial flows through the annular restriction from colliding. The flow deflector redirects the flows to smoothly recombine in the chamber outlet.

A fluid pressure regulator includes at least one fluid inlet conduit for connection to a pressurised fluid source, an outlet conduit. and an elastically expansible chamber arranged between the at least one fluid inlet conduit and the outlet conduit. The elastically expansible chamber being configured to elastically deform the at least one fluid inlet conduit upon expansion to modify the cross sectional area of the at least one fluid inlet conduit.

Apparatus for managing pressure events in protective casings and related methods are disclosed. An example apparatus includes a first body including a pressure inlet port, a pressure outlet port, and a groove defined in a wall of the first body. The example apparatus includes a gasket at least partially disposed in the groove. The example apparatus includes a second body removably coupled to the first body. The first body and the second body define a housing. An edge of the second body is to extend over the wall of the first body. The edge includes a lip. A portion of the lip includes a notch defined therein to enable a portion of the gasket to extrude from the groove in response to a pressure event in the housing.

The application discloses an infrared stove and an infrared split stove set. The infrared stove includes an outer casing, an inner cover, an ejector tube, a gas nozzle and an infrared reaction layer. The inner cover is nested with the outer casing to form a stove body. The infrared reaction layer is provided on the stove body. A first accommodating cavity is provided between the infrared reaction layer and the inner cover. A second accommodating cavity is provided between the inner cover and the outer casing. The ejector tube is arranged on the inner cover, communicates with the first accommodating cavity and the second accommodating cavity, and has a gas inlet. The gas nozzle is arranged on the outer casing, and is arranged opposite to the gas inlet and at a spacing. The infrared stove adopts flameless combustion, with more stability, more resistance to severe environments, and better windproof property.

The application discloses an infrared stove and an infrared split stove set. The infrared stove includes an outer casing, an inner cover, an ejector tube, a gas nozzle and an infrared reaction layer. The inner cover is nested with the outer casing to form a stove body. The infrared reaction layer is provided on the stove body. A first accommodating cavity is provided between the infrared reaction layer and the inner cover. A second accommodating cavity is provided between the inner cover and the outer casing. The ejector tube is arranged on the inner cover, communicates with the first accommodating cavity and the second accommodating cavity, and has a gas inlet. The gas nozzle is arranged on the outer casing, and is arranged opposite to the gas inlet and at a spacing. The infrared stove adopts flameless combustion, with more stability, more resistance to severe environments, and better windproof property.

A drip irrigation emitter includes a cover member, a base member, and a silicone-based membrane containing ferric oxide, the membrane=e located between the two members. The membrane includes liquid silicone rubber (LSR) material and ferric oxide. The ferric oxide in volumetric percentage ranges from about 0.1% to about 0.5% of the overall volume of the LSR material.

A flow control apparatus includes an adjustable pressure regulator fluidly coupled to an inlet region and an outlet region and configured to reduce a pressure from a first value in the inlet region to a second value in the outlet region, where the second value is lower than the first value; and a fixed area orifice disposed between the outlet region and an outlet opening of the apparatus, wherein a flow rate of a gas is controlled by the fixed area orifice and is discharged from the apparatus to a gas supply line. The second value is based on a setting of the adjustable pressure regulator.

A multi-outlet channel combination gas valve includes a valve body, a solenoid valve and a flow regulating mechanism. The valve body has a multiple of air outlets, at least two outlet channels formed between each air outlet and an air inlet of the valve body, a regulating port disposed in the at least two outlet channels, and the flow regulating mechanism can regulate the gas flow passing through each regulating port of the valve body at the same time, and a solenoid valve with a dual-coil electromagnet structure. When the valve is opened, a relatively larger current is passed, and then a very small current will be provided thereafter to maintain an operation by low power consumption. Therefore, this gas valve can be used without a mains power, and a low-level regulating structure is provided for presetting a low-level flow of each air outlet.

A unit (10) for the regulation or control of a fluid pressure, having at least one housing section (13, 14) and a switching film (22) connected to the at least one housing section (13, 14) for switching at pressure differentials relative to an ambient pressure acting on the switching film (22), and for the regulation, release or blocking of a flow of the fluid between an inlet (28) and a discharge (30) for the fluid. The switching film (22) is made out of a polymer material having fluorine and carbon, in particular a thermoplastic having fluorine and carbon. In this arrangement, a hole cross-section (40) of the at least one housing section (13, 14) is closed off by the switching film (22).