Improved equipment bases and methods for making and using same are disclosed herein. The equipment base can include a first coated substrate including a first part having a first thickness sized to provide the load-bearing support for the equipment, a first elastomer coating the first part, a second coated substrate positioned adjacent to the first coated substrate, the second coated substrate including a second part having a second thickness sized to provide the load-bearing support for the equipment, and a second elastomer coating the second part. A first seam can be formed between the first and second coated substrates to allow for moisture to pass between the first and second coated substrates so that moisture is allowed to seep away from the bottom of the equipment.

An auxetic structure includes a plurality of polyhedral units arranged adjacent one another to form a three-dimensional structure. Each polyhedral unit has protrusions extending orthogonally from some surfaces thereof and recesses formed in other surfaces thereof. The protrusions of each polyhedral unit are slidingly received in corresponding recesses of adjacent polyhedral units. A plurality of sleeves are positioned around each protrusion and in a corresponding recess. The sleeves are formed from a softer material than the protrusions. An auxetic effect is achieved by shear-induced displacement of the protrusions in corresponding recesses.

A method and mount assembly comprising a screw mechanism including a sleeve rotatable relative to the first housing and defining an internal screw-thread for adjusting the stiffness in the mount assembly in a vehicle. A collar non-rotatably secured to the plate and extends axially into the sleeve and defines an external screw-thread engaging the internal screw-thread of the sleeve. The internal screw-thread and the external screw-thread are self-locking in a static condition and prevent relative rotation between the sleeve and the collar below a predetermined force therebetween. A fluid pressure in the first housing overcomes the predetermined force and causes the sleeve to rotate from the static condition for moving the collar and the plate axially to change the stiffness of the pad.

A variable stiffness automotive suspension bushing (1) comprises a shaft or rod connected to a wheel member, an inner cylinder fixedly connected to the shaft or rod, and an outer cylinder fixedly connected to a chassis member. A magnetorheological (MR) elastomer, having iron particles embedded therein, is interposed between the inner and outer cylinders, and a coil is disposed about the inner cylinder. When the coil is energized by electrical current provided from a steering control module, a variable magnetic field is generated so as to influence the magnetorheological (MR) elastomer whereby variable stiffness values of the elastomer are obtained to provide the bushing (1) with variable stiffness characteristics in order to, in turn, provide the vehicle with optimal wheel deflection.

A powertrain mount includes a resilient mount that is connected to a powertrain component by a connecting arm. The resilient mount is moveable by an actuator member relative to a structural member of a motor vehicle in an opposite direction to a predicted displacement of the connecting arm so as to reduce the displacement of the powertrain component relative to a fixed point on the motor vehicle when the predicted displacement occurs. This reduces the final displacement of the powertrain component relative to a fixed point on the motor vehicle when the predicted displacement occurs and allows the use of a softer resilient mount than would otherwise be the case.

The disclosure relates to a bearing bushing for a motor vehicle. In one example, the bearing bushing has an inner ring and an outer ring and an elastomer element arranged rotationally fixedly radially between the inner ring and the outer ring. The bearing bushing is switchable between at least two stiffness stages.

The change in stiffness of the bearing bushing may be provided by at least one auxiliary element disposed radially between the inner ring and the outer ring.

A variable rate bound stopper includes a bound stopper in the form of an elastomer member. The elastomer member has an aperture such that the bound stopper is configured to be positioned over and disposed around a piston rod of a shock absorber. A shape memory alloy (SMA) coil formed from an SMA wire extends around at least a portion of the elastomer member. The SMA coil has a relaxed state and an activated state. The SMA coil constrains the elastomer member from deforming radially outward and alters an intrinsic spring rate of the bound stopper when in the activated state.

The present invention relates to a dynamic damper control device. A control unit includes a first acceleration sensor configured to obtain a first acceleration of a mass member, a second acceleration sensor configured to obtain a second acceleration of a vibration control target member, and a target amplitude amplification ratio calculating unit configured to calculate a target amplitude amplification ratio of the mass member and the vibration control target member based on the first acceleration and the second acceleration, and is configured to change a magnetic force produced from an electromagnet based on the target amplitude amplification ratio.

The disclosure relates to a bearing bushing, for example, for a motor vehicle. The bearing bushing is switchable between a first and a second stiffness stage.

The bearing bushing has a first elastomer ring, which is arranged rotationally fixedly on an outer circumferential surface of an inner ring, and a second elastomer ring, which is arranged rotationally fixedly on an inner circumferential surface of an outer ring. Radially between the two elastomer rings, an intermediate ring makes contact in a rotationally fixed manner with the two elastomer rings. To change in stiffness of the bearing bushing, the first elastomer ring can be bridged by the intermediate ring and at least one blocking ring which is arranged on the bearing bushing at an end side.

The disclosure relates to bearing bushes for a motor vehicle, in which the bearing bushing may be switchable between a first and a second stiffness stage.

The bearing bushing may include a first elastomer ring, which is arranged at least indirectly on an outer circumferential surface of a bolt, and a second elastomer ring, which is arranged radially between a first and second sleeve. The second sleeve may be arranged radially between the first and the second elastomer rings. In order to change the stiffness stage of the bearing bushing, the two sleeves may be connectable to one another by at least one ring which comes into contact with said sleeves at an end side.