A thermal trigger assembly for remote mechanical actuation of another fire protection system component includes an activation component having a base and a movable member. A bias member biases the movable member from a preactivation to an activated position with respect to the base. A thermally responsive element retains the movable member in the preactivation position until a predetermined thermodynamic condition is reached, when the thermally responsive element loses structural integrity. A flexible connector includes a flexible hollow outer cable housing with one end configured to be stationarily (preferably fixedly) connected with the base. A flexible cable is inside the outer cable housing for sliding movement therein and has one end configured to be stationarily (preferably fixedly) connected with the movable member. The flexible cable is moved with respect to the outer cable housing by movement of the movable member upon loss of structural integrity by the thermally responsive element.

A test valve including a body, a test assembly, a relief assembly, and a drain assembly. The body includes an inlet, an outlet, an internal wall isolating the inlet from the outlet, and a drain opening, a relief opening, and a test opening defined by the internal wall and structured to facilitate fluid communication between the inlet and the outlet. The test assembly is structured to seal and unseal the test opening to selectively fluidly couple the inlet and the outlet. The relief assembly is structured to seal and unseal the relief opening to selectively fluidly couple the inlet and the outlet. The drain assembly is structure to seal and unseal the drain opening to selectively fluidly couple the inlet and the outlet.

A test valve including a body, a test assembly, a relief assembly, and a drain assembly. The body includes an inlet, an outlet, an internal wall isolating the inlet from the outlet, and a drain opening, a relief opening, and a test opening defined by the internal wall and structured to facilitate fluid communication between the inlet and the outlet. The test assembly is structured to seal and unseal the test opening to selectively fluidly couple the inlet and the outlet. The relief assembly is structured to seal and unseal the relief opening to selectively fluidly couple the inlet and the outlet. The drain assembly is structure to seal and unseal the drain opening to selectively fluidly couple the inlet and the outlet.

A dry sprinkler is provided that includes a conduit with a fluid inlet and a fluid outlet, a valve positioned near the fluid inlet and a fire sprinkler head that is positioned near the fluid outlet. The fire sprinkler head is operably connected to the valve by a tie. When the fire sprinkler head reacts to an elevated temperature condition, the tie is engaged and is operable to open the valve. In a normal state, before the fire sprinkler head reacts, the tie can be unbiased toward the fire sprinkler head. The tie can also be non-rigid and/or in a non-compressed state within the conduit. The conduit of the dry sprinkler can be flexible.

A dry sprinkler is provided that includes a conduit with a fluid inlet and a fluid outlet, a valve positioned near the fluid inlet and a fire sprinkler head that is positioned near the fluid outlet. The fire sprinkler head is operably connected to the valve by a tie. When the fire sprinkler head reacts to an elevated temperature condition, the tie is engaged and is operable to open the valve. In a normal state, before the fire sprinkler head reacts, the tie can be unbiased toward the fire sprinkler head. The tie can also be non-rigid and/or in a non-compressed state within the conduit. The conduit of the dry sprinkler can be flexible.

A dry sprinkler has a casing tube having an inlet orifice and an outlet orifice. When the sprinkler is in a non-actuated state, an inlet seal assembly operatively seals the inlet orifice and an outlet seat assembly operatively seals the outlet orifice. A translating member extends through the casing tube between an inlet and an outlet. The translating member axially translates from a first position, in which the translating member retains the inlet seal assembly in a sealed state, to a second position, in which the translating member releases the inlet seal assembly, toward the outlet when the outlet seat assembly is released. The sprinkler has a nominal K-factor greater than 17 gpm/(psi).sup.1/2. In addition, a difference between a cross-sectional area of the casing tube and a cross-sectional area bounded by an outer perimeter of the translating member is more than 30% of the cross-sectional area of the casing tube.

A dry sprinkler has a casing tube having an inlet orifice and an outlet orifice. When the sprinkler is in a non-actuated state, an inlet seal assembly operatively seals the inlet orifice and an outlet seat assembly operatively seals the outlet orifice. A translating member extends through the casing tube between an inlet and an outlet. The translating member axially translates from a first position, in which the translating member retains the inlet seal assembly in a sealed state, to a second position, in which the translating member releases the inlet seal assembly, toward the outlet when the outlet seat assembly is released. The sprinkler has a nominal K-factor greater than 17 gpm/(psi).sup.1/2. In addition, a difference between a cross-sectional area of the casing tube and a cross-sectional area bounded by an outer perimeter of the translating member is more than 30% of the cross-sectional area of the casing tube.

An installation for testing open fire extinguishing systems includes a smoke and/or mist generator and a connecting conduit suitable and dedicated for being connected to a fire fighting system. A method for testing of fire extinguishing systems has the following steps performed in any suitable order: a) providing an installation for the generation of smoke and/or mist, b) connecting a conduit of the installation to a conduit of a first section of a preferably open fire extinguishing system, c) opening a valve which provides a connection between the first section of the fire fighting system and the connecting conduit of the installation, d) turning on the smoke and/or mist generator, such that, by the exiting of the smoke and/or mist, the spray heads of the first section of the fire extinguishing system can be inspected on their openness, e) repeating steps b-d for any further section of the fire extinguishing system.

An installation for testing open fire extinguishing systems includes a smoke and/or mist generator and a connecting conduit suitable and dedicated for being connected to a fire fighting system. A method for testing of fire extinguishing systems has the following steps performed in any suitable order: a) providing an installation for the generation of smoke and/or mist, b) connecting a conduit of the installation to a conduit of a first section of a preferably open fire extinguishing system, c) opening a valve which provides a connection between the first section of the fire fighting system and the connecting conduit of the installation, d) turning on the smoke and/or mist generator, such that, by the exiting of the smoke and/or mist, the spray heads of the first section of the fire extinguishing system can be inspected on their openness, e) repeating steps b-d for any further section of the fire extinguishing system.

Sectional fire protection systems and methods for the protection of an attic space are provided. A fluid control thermal detection device is located above a ceiling base within a spherical radial distance proximate a peak region of the attic space. An open fluid distribution device is disposed between the roof deck and the ceiling base and connected to the fluid control thermal detection device for receipt of firefighting fluid from the fluid control thermal detection device.