The present invention provides a gas generator including, an ignition device chamber, a gas inflow chamber, and a pressurized gas chamber being arranged from a first end fixed with an ignition device to a second end opposite thereto in a cylindrical housing, an inner circumferential wall surface of the cylindrical housing, from the ignition device chamber to the gas inflow chamber, having a first movement restricting portion, a second movement restricting portion and a stopping portion which are arranged in an axial direction at intervals in the above order so as to protrude, the second movement restricting portion having an ignition device chamber-side surface which is an inclined surface decreasing an inner diameter of the housing from the side of the ignition device chamber to the side of the gas inflow chamber and a gas inflow chamber-side surface whose angle (α1) with respect to the cylindrical housing is not more than 90 degrees, so that an axial cross-sectional shape of the second movement restricting portion is a triangle, a breaking device being arranged between the ignition device chamber and the gas inflow chamber and including a base whose outer circumferential surface abuts against an inner circumferential wall surface of the cylindrical housing and a distal end having an enlarged-diameter portion, and before actuation, the base being held between the first movement restricting portion and the second movement restricting portion, after actuation, the base being held between the surface of the second movement restricting portion whose angle al is not more than 90 degrees and the stopping portion.

The present invention provides a gas generator, including in a cylindrical housing, an ignition device chamber provided with an ignition device, a gas inflow chamber having a gas discharge port and a pressurized gas chamber being arranged in the above order from the first end, a rupturable plate closing between the pressurized gas chamber and the gas inflow chamber and being fixed to an annular fixing portion, a breaking device for the rupturable plate being arranged between the ignition device chamber and the gas inflow chamber, the breaking device including a base, a rod main body which extends from the base towards the rupturable plate, and an enlarged-diameter portion at a distal end of the rod main body, and during actuation, the base moving in the axial direction, the enlarged-diameter portion being positioned inside the pressurized gas chamber after punching out the rupturable plate, and the rod main body portion being positioned so as to oppose the annular fixing portion in a radial direction, a pressurized gas passing through a gas passage and then is discharged from the gas discharge port, the gas passage including a first annular passage in which a width between the enlarged-diameter portion and the annular fixing portion varies and a second annular passage between the rod main body portion and the annular fixing portion, a cross-sectional area of the second annular passage being the smallest among the cross-sectional area of the second annular passage, an area of a minimum width portion of the first annular passage and a total opening area of the gas discharge port, and Q<(A2−A1) being satisfied when Q denotes the cross-sectional area of the second annular passage, A1 denotes an area of the punched-out rupturable plate and A2 denotes the area of the minimum width portion of the first annular passage.

The present invention provides a gas generator, including in a cylindrical housing, an ignition device chamber provided with an ignition device, a gas inflow chamber having a gas discharge port and a pressurized gas chamber being arranged in the above order from the first end, a rupturable plate closing between the pressurized gas chamber and the gas inflow chamber and being fixed to an annular fixing portion, a breaking device for the rupturable plate being arranged between the ignition device chamber and the gas inflow chamber, the breaking device including a base, a rod main body which extends from the base towards the rupturable plate, and an enlarged-diameter portion at a distal end of the rod main body, and during actuation, the base moving in the axial direction, the enlarged-diameter portion being positioned inside the pressurized gas chamber after punching out the rupturable plate, and the rod main body portion being positioned so as to oppose the annular fixing portion in a radial direction, a pressurized gas passing through a gas passage and then is discharged from the gas discharge port, the gas passage including a first annular passage in which a width between the enlarged-diameter portion and the annular fixing portion varies and a second annular passage between the rod main body portion and the annular fixing portion, a cross-sectional area of the second annular passage being the smallest among the cross-sectional area of the second annular passage, an area of a minimum width portion of the first annular passage and a total opening area of the gas discharge port, and Q<(A2−A1) being satisfied when Q denotes the cross-sectional area of the second annular passage, A1 denotes an area of the punched-out rupturable plate and A2 denotes the area of the minimum width portion of the first annular passage.

A pressurized gas mechanism contains a sealed gas container containing a sealed first end, and, a burst cup sealing the first end and containing a rupturable portion. A housing encases the burst cup and is juxtaposed to at least a portion of the sealed gas container, the housing containing a surface juxtaposed to the rupturable portion. Upon actuation of the mechanism, the rupturable portion is adapted to rupture as the rupturable portion is leveraged against the surface, thereby releasing gas from the sealed gas container.

A firing mechanism (25) for activation of a pneumatic stored energy system having a motor (50) connected to a vessel (20) by a tether, the vessel (20) containing a pressurised fluid. Activation of the motor (50) causes the tether to wind, applying a linear force to an attachment region of the vessel, fracturing the vessel (20) to release the pressurised fluid thereby activating the pneumatic stored energy system.

A firing mechanism (25) for activation of a pneumatic stored energy system having a motor (50) connected to a vessel (20) by a tether, the vessel (20) containing a pressurised fluid. Activation of the motor (50) causes the tether to wind, applying a linear force to an attachment region of the vessel, fracturing the vessel (20) to release the pressurised fluid thereby activating the pneumatic stored energy system.

The invention relates to a hybrid inflator (10) comprising a combustion chamber (20) and a pressure gas tank (30), wherein in the idle state of the hybrid inflator (10) an outlet opening (31) of the pressure gas tank (30) is closed by a bursting element (32) which in the case of function of the hybrid inflator (10) can be destroyed by means of a penetration element (40), wherein a mixing chamber (70) is formed between the pressure gas tank (30) and the combustion chamber (20). In accordance with the invention, between the combustion chamber (20) and the mixing chamber (70) at least in portions a partition wall (80) having a combustion chamber side (81) and a mixing chamber side (82) is formed, wherein the partition wall (80) includes at least one combustion chamber opening (85) which in the idle state of the hybrid inflator (10) is closed by a cover (88) formed on the mixing chamber side (82) of the partition wall (80).

The invention relates to a hybrid inflator (10) comprising a combustion chamber (20) and a pressure gas tank (30), wherein in the idle state of the hybrid inflator (10) an outlet opening (31) of the pressure gas tank (30) is closed by a bursting element (32) which in the case of function of the hybrid inflator (10) can be destroyed by means of a penetration element (40), wherein a mixing chamber (70) is formed between the pressure gas tank (30) and the combustion chamber (20). In accordance with the invention, between the combustion chamber (20) and the mixing chamber (70) at least in portions a partition wall (80) having a combustion chamber side (81) and a mixing chamber side (82) is formed, wherein the partition wall (80) includes at least one combustion chamber opening (85) which in the idle state of the hybrid inflator (10) is closed by a cover (88) formed on the mixing chamber side (82) of the partition wall (80).

A cold gas generator for a vehicle includes a container for storing gas, and an outlet opening closed by a closure element. The apparatus for operating the cold gas generator has a first terminal for a first connecting line for providing a first operating voltage potential, and a second terminal for a second connecting line for providing a second operating voltage potential. The apparatus also has an electrical coil to actuate, in response to a coil current, a closure device for controlling a gas flow through the outlet opening, the coil being connected between the first terminal and the second terminal. The apparatus also has a firing device to open the closure element in response to a firing current, the firing device being connected between the first terminal and the second terminal.

A cold gas generator for a vehicle includes a container for storing gas, and an outlet opening closed by a closure element. The apparatus for operating the cold gas generator has a first terminal for a first connecting line for providing a first operating voltage potential, and a second terminal for a second connecting line for providing a second operating voltage potential. The apparatus also has an electrical coil to actuate, in response to a coil current, a closure device for controlling a gas flow through the outlet opening, the coil being connected between the first terminal and the second terminal. The apparatus also has a firing device to open the closure element in response to a firing current, the firing device being connected between the first terminal and the second terminal.