In an embodiment, a method of forming a cooling plate, comprises laser welding a plurality of weld lines to physically connect a first substrate and a second substrate wherein the plurality of weld lines forms an inflatable track; and inflating the inflatable track with an inflation fluid to form a cooling channel in the cooling plate. In another embodiment, the cooling plate can comprise a first substrate and a second substrate and a plurality of weld lines can form a fluid tight seal for a cooling channel located therebetween.

In an embodiment, a method of forming a cooling plate, comprises laser welding a plurality of weld lines to physically connect a first substrate and a second substrate wherein the plurality of weld lines forms an inflatable track; and inflating the inflatable track with an inflation fluid to form a cooling channel in the cooling plate. In another embodiment, the cooling plate can comprise a first substrate and a second substrate and a plurality of weld lines can form a fluid tight seal for a cooling channel located therebetween.

Adapter suitable to connect a device for allowing compressed gas to pass through the adapter into an inflatable member, where the adapter comprises: —Means for attaching the adapter to a source of compressed gas, said means having a gas passage, and where the means for attaching the adapter is in gas communication with —A main housing, where the housing has an inner open-ended cavity, suitable to receive a valve body of the inflatable member, and where inside said open-ended cavity, a gas outlet is arranged, and further where means for releasably holding the valve body of the inflatable member is provided and further —A resilient gasket is provided surrounding the gas outlet, where in one end of the gasket towards the opening of the open-ended cavity is provided an engagement surface and in a lower section of the gasket opposite the engagement surface is provided a cavity, where the cavity is limited by an inner lip and an outer lip, where said inner lip is in sealing and sliding engagement with the gas outlet and the outer lip is in sealing and sliding engagement with the main housing, such that the cavity in the low-er end of the gasket creates a substantially gas tight chamber and where the gasket is further provided with a shoulder, and where a ridge is provided inside said open-ended cavity, where the open-ended cavity in a first cross-section perpendicular to the gas passage through the ridge has a smaller cross-sectional area of the gas passage than in a second cross-section adjacent the shoulder, such that the ridge limits the movement of the gasket in the gas passage's direction, and where the gas passage has a gas connection to the substantially gas tight chamber provided between the lower section of the gasket, and the housing.

Adapter suitable to connect a device for allowing compressed gas to pass through the adapter into an inflatable member, where the adapter comprises: —Means for attaching the adapter to a source of compressed gas, said means having a gas passage, and where the means for attaching the adapter is in gas communication with —A main housing, where the housing has an inner open-ended cavity, suitable to receive a valve body of the inflatable member, and where inside said open-ended cavity, a gas outlet is arranged, and further where means for releasably holding the valve body of the inflatable member is provided and further —A resilient gasket is provided surrounding the gas outlet, where in one end of the gasket towards the opening of the open-ended cavity is provided an engagement surface and in a lower section of the gasket opposite the engagement surface is provided a cavity, where the cavity is limited by an inner lip and an outer lip, where said inner lip is in sealing and sliding engagement with the gas outlet and the outer lip is in sealing and sliding engagement with the main housing, such that the cavity in the low-er end of the gasket creates a substantially gas tight chamber and where the gasket is further provided with a shoulder, and where a ridge is provided inside said open-ended cavity, where the open-ended cavity in a first cross-section perpendicular to the gas passage through the ridge has a smaller cross-sectional area of the gas passage than in a second cross-section adjacent the shoulder, such that the ridge limits the movement of the gasket in the gas passage's direction, and where the gas passage has a gas connection to the substantially gas tight chamber provided between the lower section of the gasket, and the housing.

A coupling manifold assembly has both regulated and unregulated flow orientations and includes a manifold body and a pressure regulator couplably received into the manifold body. The manifold body includes a pair of connection ports between which flow is movable through the manifold body, with the pressure regulator being received into a flow path between the connection ports. The pressure regulator is configured to regulate flow in a first direction between the connection ports and to allow for unregulated flow in an opposite second direction between the connection ports.

A coupling manifold assembly has both regulated and unregulated flow orientations and includes a manifold body and a pressure regulator couplably received into the manifold body. The manifold body includes a pair of connection ports between which flow is movable through the manifold body, with the pressure regulator being received into a flow path between the connection ports. The pressure regulator is configured to regulate flow in a first direction between the connection ports and to allow for unregulated flow in an opposite second direction between the connection ports.

In an embodiment, a method of forming a cooling plate, comprises laser welding a plurality of weld lines to physically connect a first substrate and a second substrate wherein the plurality of weld lines forms an inflatable track; and inflating the inflatable track with an inflation fluid to form a cooling channel in the cooling plate. In another embodiment, the cooling plate can comprise a first substrate and a second substrate and a plurality of weld lines can form a fluid tight seal for a cooling channel located therebetween.

In an embodiment, a method of forming a cooling plate, comprises laser welding a plurality of weld lines to physically connect a first substrate and a second substrate wherein the plurality of weld lines forms an inflatable track; and inflating the inflatable track with an inflation fluid to form a cooling channel in the cooling plate. In another embodiment, the cooling plate can comprise a first substrate and a second substrate and a plurality of weld lines can form a fluid tight seal for a cooling channel located therebetween.

A coupling manifold assembly has both regulated and unregulated flow orientations and includes a manifold body and a pressure regulator couplably received into the manifold body. The manifold body includes a pair of connection ports between which flow is movable through the manifold body, with the pressure regulator being received into a flow path between the connection ports. The pressure regulator is configured to regulate flow in a first direction between the connection ports and to allow for unregulated flow in an opposite second direction between the connection ports.

A coupling manifold assembly has both regulated and unregulated flow orientations and includes a manifold body and a pressure regulator couplably received into the manifold body. The manifold body includes a pair of connection ports between which flow is movable through the manifold body, with the pressure regulator being received into a flow path between the connection ports. The pressure regulator is configured to regulate flow in a first direction between the connection ports and to allow for unregulated flow in an opposite second direction between the connection ports.