Abstract: A mechanical linear actuator having a tubular member that is defined by a housing for rotatably and axially supporting a circular nut, a lead screw is mated to the circular nut so that it can move axially in and out of the tubular member. A torsion spring clutch brake is wound about the circular nut to normally brake the nut and thus prevent the lead screw from moving into or out of the tubular member. An unlocking mechanism can remotely unwind the torsion spring clutch brake to sufficiently release the circular nut and thus allow the lead screw to pass in and out of the tubular member. An adjustable stop is provided for adjusting the stroke of the actuator.

Abstract: A shock and vibration isolator that includes a double acting mechanical spring assembly that is mounted to act in parallel with a fluid or liquid spring assembly. The mechanical spring is arranged to provide a first spring rate over a first displacement range and a second spring rate over a further second displacement range. The liquid spring is connected to an accumulator by control circuitry that is under the control of a microprocessor to release stored energy which combines with that of the mechanical spring to rapidly dissipate the input G forces to a level sufficient to protect a substructure.

Abstract: A shock and vibration isolator that includes a double acting mechanical spring assembly that is mounted to act in parallel with a fluid or liquid spring assembly. The mechanical spring is arranged to provide a first spring rate over a first displacement range and a second spring rate over a further second displacement range. The liquid spring is connected to an accumulator by control circuitry that is under the control of a microprocessor to release stored energy which combines with that of the mechanical spring to rapidly dissipate the input G forces to a level sufficient to protect a substructure.

Abstract: A single-use damping mechanism. A piston assembly fits within a chamber defined by a piston receiving member. The distal end of the piston receiving member includes a first and second passages which are disposed in fluidic series between the chamber and the ambient air. The first, inner passage is relatively small and controls the damping time of the mechanism. The second, outer passage is relatively large and holds a sealing assembly that prevents fluid from escaping from the chamber, through the first passage, until the mechanism is to be used. The piston assembly includes a pressure relief assembly, which comprises a cavity filled with a compressible material, into and out of which fluid can flow as necessary to protect the mechanism from temperature related pressure changes, and yet which does not interfere with the damping characteristics of the mechanism.

Abstract: A shock and vibration isolator system that includes a frame in which a shock and vibration sensitive mass is suspended by double acting shock absorbers with vibration isolation capabilities. Wire rope isolators are also mounted between walls of the mass and adjacent walls of the frame so that shock and vibrations moving along the vertical, horizontal and longitudinal axes of the system are effectively attenuated.

Abstract: A wire rope vibration isolator employing a wire cable passed in a continuous loop through lateral hollow, cylindrical members, holes, channels or the like, formed therethrough in one or more mounting blocks or entrapment members. The mounting blocks manipulate the wire cable into a geometric shape, such as a coil or helix, that is capable of imparting elastic, spring-like qualities in the wire rope. The geometric shape of the wire rope is maintained and secured by driving dowel pins of sufficient length through the outer surface of the mounting block into the lateral hole contained therein to stake the wire rope into locking contact with the mounting block. The dowel pins are composed of material that has a harder consistency than the material composing the mounting block and wire rope. The ends of the dowel pins not engaging the wire rope are pressed flush to the top surface of the mounting block.

Abstract: A wire rope isolator having a pair of opposed mounting blocks, each having parallel holes formed therein so that the holes in one block are perpendicular to holes in the second block. One block contains two parallel holes passing through the block while the second contains three parallel holes, one of which passes through the block and the remaining holes being blind holes passing inwardly from opposite sides of the block. One end of the rope is secured in one blind hole and the rope is threaded through the block in a clover leaf pattern and the opposite end secured in the other blind hole.

Abstract: A wire rope isolator includes a wire rope and a pair of mounting blocks. The mounting blocks comprise of a pair of cylindrical elongated end flanges that are connected tangentially to each other by a web that has a thickness that is less than the diameter of the flanges thereby allowing the lower section of each flange to extend downward from each web. A hole passes axially through each flange. Wire rope is passed through each flange hole so that the lower surface of each web faces that of the other web and the pair of flanges of one mounting block are offset 90° to the pair of flanges of the opposing mounting block. Four U-shaped half loops of wire rope, with sufficient slack to impart elastic qualities to the wire rope, are formed. The U-shaped half loops extend outward at angles of about 45° from the mounting blocks in a cloverleaf formation.

Abstract: A double acting shock isolator that includes a cylindrical housing having a radially expanded chamber therein. The housing is closed at one end and open at the other end and a connector is mounted at the closed end. A stack of friction rings are mounted in a preloaded condition between the ends of the expanded chamber and a rod passes into the open end of the housing and through the stack. A pair of spaced apart raised flanges are mounted upon the rod that engages either end of the stack. A second connector is mounted upon the distal end of the rod outside of the housing so that the stack of friction rings is further compressed uniformly when either a tensile force or a compressive force is applied to the connectors.

Abstract: Apparatus for preventing the unwanted extension of a hydraulic lock when the lock is subjected to relatively high dynamic loads. The lock includes a hydraulic cylinder having a piston slidably mounted therein. The piston is secured to a piston rod which passes outwardly through one end wall of the cylinder. The lock is placed in tension when the piston rod is being extended and in compression when the rod is being retracted. A flow channel is formed in the piston through which fluid is exchanged from one side of the piston to the other. A manually operated spring biased control valve is mounted in the flow channel which is normally held closed by a set spring. Fluid is allowed to flow when the valve is manually opened or when the lock is placed in tension by some external force that overcomes the biasing force of the set spring. A velocity sensitive restrictor is also mounted in the flow channel that closes the channel when the lock is placed in tension by a dynamic force above a predetermined velocity.

Abstract: Apparatus for both attenuating vibrations below a given load and absorbing shock above the given load. A hydraulic damper unit is equipped with a spring that preloads the device and positions the damper in a neutral or centered position. The spring holds the damper unit centered until the preload force is exceeded in either tension or compression. Elastomeric rod ends connect the damper unit to a mass to be protected and a supporting structure. The elastomeric rod ends have a response such that they attenuate vibrations up to the preloading force of the spring whereupon the elastomer is fully compressed thus permitting the damper to be displaced to absorb shock loads that are greater than the preload break-away force.

Abstract: A damper is provided which includes a first cylinder containing a viscous fluid. The first cylinder is sealed at both ends by end plates. The first cylinder is adapted for connection to a structure such as a building or a bridge. A piston head within the first cylinder is adapted for reciprocation with respect to the first cylinder. A piston rod is connected to the piston head. The other end of the piston rod extends through the end plate and is adapted for connection to the structure. A second piston rod extends from the piston head through the second end plate. A first ring surrounds the piston head and is constructed from a material having a high coefficient of thermal expansion such as plastic. A second ring surrounds the first ring and is constructed from a material having a low coefficient of thermal expansion such as metal.

Abstract: A rotary friction damper in a device for connecting a door to an adjacent structure such that the door pivots about an axis during opening and closing of the same and including a torsion spring operatively connected to the door and to the structure for movement about the pivot axis to store energy during opening of the door and to release energy to provide closing during closing of the door. The rotary friction damper is operatively associated with the torsion spring and has an axis of rotation disposed substantially parallel to the pivot axis for controlling the door closing speed. A damper housing rotates in response to application of input rotational force, and damper shoes within the housing are moved radially outwardly into frictional engagement with the housing. An arrangement of disc springs applies biasing force in a direction parallel to the axis of rotation of the damper, and the biasing force is directed to cause radial outward movement of the shoes.

Abstract: A rotary friction damper in a device for connecting a door to an adjacent structure such that the door pivots about an axis during opening and closing of the same and including a torsion spring operatively connected to the door and to the structure for movement about the pivot axis to store energy during opening of the door and to release energy to provide closing during closing of the door. The rotary friction damper is operatively associated with the torsion spring and has an axis of rotation disposed substantially parallel to the pivot axis for controlling the door closing speed. The rotary friction damper is adjustable and variable. A mechanism operatively associated with the damper varies the resistance of the damper to movement of the torsion spring to produce a controlled uniform closing speed of the door and for reducing the resistance of the damper to movement of the torsion spring when the door nears the closed position to allow the torsion spring to close the door in an unrestricted manner.

Abstract: A dasphpot damper for acting between two objects subject to move toward and away from one another including a housing including an elongated cavity, a piston mounted within the housing cavity for reciprocating movement therealong and dividing the cavity into two variable-volume, hydraulic fluid chambers, and a network of passages permitting hydraulic fluid to flow between the two variable-volume chambers as the housing and piston move relative to one another in response to relative movements between the two objects utilizes unitary flow control cartridge mounted within the housing and defining a passageway through which hydraulic fluid is forced to flow when passing between the two variable-volume chambers. The flow control cartridge also includes a check valve device associated with the passageway for controllably restricting the flow of hydraulic fluid in one direction through the passageway and for permitting substantially unrestricted flow of hydraulic fluid in the other direction through the passageway.

Abstract: A stroke-limiting stop for a fluid locking device wherein movement between a piston and cylinder is influenced by fluid in the device, the stop comprising a housing having internal shape and dimension enabling one end of the cylinder to move longitudinally within at least one formation on the inner surface of the housing, and a stop element within the housing and having a portion adapted to engage the formation establishing a fixed position on the stop element along the housing longitudinal axis, the stop element being supported within the housing for movement between positions wherein the portion of the element either engages the formation or is out of engagement therewith with so that the stop element in the first position acts as an abutment to contact the cylinder upon movement into the housing thereby limiting the extent of relative movement between the piston and cylinder.

Abstract: A shock absorber comprising a housing assembly including an elongated cavity for containing hydraulic fluid, an annular cavity surrounding the elongated cavity, a piston assembly including a head slidably received by the elongated cavity and a rod joined to the head for movement therewith, a compressible bladder containing gas under pressure positioned within the annular cavity, and a plurality of orifices defined within the housing assembly through which the elongated and annular cavities communicate with one another. The rod extends through the housing assembly and is movable with the piston head between extended and retracted conditions. The bladder is positioned within the annular cavity so as to extend along at least a portion of the annular cavity and leave uncovered a portion of the inner wall. The plurality of orifices are arranged in a pattern along the uncovered portion of the inner wall.

Abstract: A dasphpot damper for acting between two objects subject to move toward and away from one another including a housing including an elongated cavity, a piston mounted within the housing cavity for reciprocating movement therealong and dividing the cavity into two variable-volume, hydraulic fluid chambers, and a network of passages permitting hydraulic fluid to flow between the two variable-volume chambers as the housing and piston move relative to one another in response to relative movements between the two objects utilizes unitary flow control cartridge mounted within the housing and defining a passageway through which hydraulic fluid is forced to flow when passing between the two variable-volume chambers. The flow control cartridge also includes a check valve device associated with the passageway for controllably restricting the flow of hydraulic fluid in one direction through the passageway and for permitting substantially unrestricted flow of hydraulic fluid in the other direction through the passageway.

Abstract: An adjustable kinetic energy absorbing device wherein a piston is moved in response to an applied impact force along within a tube defining a chamber containing hydraulic fluid. The tube has a plurality of orifice openings therein spaced therealong in the direction of movement of the piston, and an elongated path is defined outwardly of the chamber, preferably in the outer surface of the tube, and in fluid communication with the orifice openings. The path is relatively narrow in width and extends along the tube. An elongated flow control element is supported in the device and movable lengthwise along the path in response to manual operation of an adjustment assembly including a cam operatively engaging the elongated element. The flow control element has formations spaced therealong adapted to register with the orifice openings to control flow of hydraulic fluid through the openings in response to movement of the element.