A thermally stabilized fastener system and method is disclosed. The disclosed system/method integrates a fastener (FAS) incorporating a faster retention head (FRH), fastener retention body (FRB), and fastener retention tip (FRT) to couple a mechanical member stack (MMS) in a thermally stabilized fashion using a fastener retention receiver (FRR). The MMS includes a temperature compensating member (TCM), a first retention member (FRM), and an optional second retention member (SRM). The TCM is constructed using a tailored thermal expansion coefficient (TTC) that permits the TCM to compensate for the thermal expansion characteristics of the FAS, FRM, and SRM such that the force applied by the FRH and FRR portions of the FAS to the MMS is tailored to a specific temperature force profile (TFP) over changes in MMS/FAS temperature. The TCM may be selected with a TTC to achieve a uniform TFP over changes in MMS/FAS temperature.

A fitting in a mechanical control system having a jack for the displacement of an actuator. When a stroke of the jack is impeded by a problem in the kinematic chain, the jack continues to push with increased intensity and may damage one or more elements of the mechanism for transmitting the movement, or even more. A frangible part, having a weak point that can withstand up to a certain force threshold is provided in the fitting. Beyond this threshold, the part breaks and allows the jack to continue its stroke so as to not damage the overall system, in both directions of displacement of the jack.

A fitting in a mechanical control system having a jack for the displacement of an actuator. When a stroke of the jack is impeded by a problem in the kinematic chain, the jack continues to push with increased intensity and may damage one or more elements of the mechanism for transmitting the movement, or even more. A frangible part, having a weak point that can withstand up to a certain force threshold is provided in the fitting. Beyond this threshold, the part breaks and allows the jack to continue its stroke so as to not damage the overall system, in both directions of displacement of the jack.

A breakaway nut fastener is provided having a hybrid construction of plastic and metal. The breakaway nut fastener includes a head portion and a nut portion connected by a thin walled section. The head portion is made of plastic and has a shape so as to mate to a tool. The nut portion has an exterior shell having a cavity for receiving a nut insert. The nut portion's exterior shell is made of plastic while the nut insert is made of metal. The breakaway nut fastener's thin walled section is also made of plastic joining the breakaway nut fastener's head portion and the nut portion's exterior shell. The thin walled section is made of plastic, and preferably the head portion, nut portion and thin walled section are constructed as one part forming a single component of plastic.

A breakaway nut fastener is provided having a hybrid construction of plastic and metal. The breakaway nut fastener includes a head portion and a nut portion connected by a thin walled section. The head portion is made of plastic and has a shape so as to mate to a tool. The nut portion has an exterior shell having a cavity for receiving a nut insert. The nut portion's exterior shell is made of plastic while the nut insert is made of metal. The breakaway nut fastener's thin walled section is also made of plastic joining the breakaway nut fastener's head portion and the nut portion's exterior shell. The thin walled section is made of plastic, and preferably the head portion, nut portion and thin walled section are constructed as one part forming a single component of plastic.

A separating device including a release ring able to slide along a segmented nut, the release ring being configured to move between a first position wherein the segments of the nut are retained around a fastening screw and a second position wherein the segments of the nut are released, said device being characterized in that the release ring is moreover configured to travel a determined distance between the second position and a third position wherein said ring is in contact with a damping element located between said ring and an annular shutter, the release ring not being in contact with the damping element between the second position and the third position.

A high-voltage battery quick release system for an electrified vehicle and related method for using same is provided. In one exemplary implementation, the high-voltage battery quick release system includes a first quick release switch that sends an activation signal indicative of a battery disconnect request. A mechanical decoupled is configured to mechanically decouple the high-voltage battery from the vehicle. An electrical decoupler is configured to electrically disconnect the high-voltage battery from the vehicle. A controller receives a signal from the first quick release switch and, responsive to the activation signal, (i) sends a signal to the mechanical decoupler that mechanically decouples the high-voltage battery from the vehicle and (ii) electrically disconnects the high-voltage battery from the vehicle.

A bolt which extends into the first casing part, into the hole in the barrel nut, and into the second casing part, wherein the bolt engages with the barrel nut so as to join the first casing part to the second casing part; wherein the barrel nut includes a first portion and a second portion, wherein the first portion of the barrel nut is structurally weaker than the second portion of the barrel nut such that, if a predetermined load between the first casing part and the second casing part is exceeded, the first portion of the barrel nut becomes crushed while the second portion of the barrel nut remains engaged with the bolt. The casing assembly may be included in a gas turbine engine.

A bolt which extends into the first casing part, into the hole in the barrel nut, and into the second casing part, wherein the bolt engages with the barrel nut so as to join the first casing part to the second casing part; wherein the barrel nut includes a first portion and a second portion, wherein the first portion of the barrel nut is structurally weaker than the second portion of the barrel nut such that, if a predetermined load between the first casing part and the second casing part is exceeded, the first portion of the barrel nut becomes crushed while the second portion of the barrel nut remains engaged with the bolt. The casing assembly may be included in a gas turbine engine.

An active bolt release arrangement includes a nut having nut portions adapted for radial movement, a sleeve part encircling the nut and having contact portions in contact with the nut portions in order to prevent the nut portions from radial movement, and a pyrotechnical actuator. The pyrotechnical actuator is adapted for, upon deployment, moving the sleeve part relative to the nut to a released position forming a release space allowing radial movement of the nut portions. The pyrotechnical actuator is arranged for turning, upon deployment, the sleeve part a predetermined rotational distance to the released position, such that radial movement of the nut portions by formation of the release space is allowed, thereby causing release of a bolt connected to the bolt release arrangement.