A torque rod includes a small ring section to be connected to an engine, a large ring section to be connected to a vehicle body, and a rod section providing a connection between the small ring section and the large ring section. The large ring section includes an outer member connected to the rod section, an inner member to be connected to the vehicle body, and a large ring elastic member providing a connection between the outer member and the inner member. Based on a transmission characteristic map, which is prepared by mapping transmission characteristics of the torque rod that are determined by a rod length, a small ring torsion spring, a large ring spring and a large ring spring ratio as parameters, such a combination of parameters that the transmission characteristics are less than 100 N/mm is selected.

A bearing element (1) for mounting a component, especially a cooling module, with an elastomeric element (12), the elastomeric element (12) having an inner connection (6) for connecting to a bearing pin (7) of the component to be mounted, an outer connection (8) for connecting to a bearing frame (10), and at least one support arm (14), which extends between the inner connection (6) and outer connection (8) and elastically connects these together, with a force transfer surface (16) of the outer connection (8) to the bearing frame (10) formed by an outer end face of the support arm (10), and the bearing element (1) formed such that, in the event of an elastic displacement of the inner connection (6) relative to the outer connection (8) in a predetermined, radial displacement direction relative to the bearing element (1) the support arm (14) is stressed predominantly by thrust.

A damper for damping vibrations of a structure comprises: a first damping unit, comprising a first damping body having a first mass (m.sub.1), a first spring element having a first spring constant (k.sub.1) and a first damping element having a first damping constant (c.sub.1), wherein said first damping body is configured to be attached to said structure via said first spring element and said first damping element; and a second damping unit, comprising a second damping body having a second mass (m.sub.2), a second spring element having a second spring constant (k.sub.2) and a second damping element having a second damping constant (c.sub.2), wherein said second damping body is configured to be attached to said first damping body via said second spring element and said second damping element.

A vibration damper including a frame having at least a first cavity, a frame first end and a frame second end spaced from the frame first end; a shaft slidably coupled to and extending into the frame where the shaft extends through the first cavity; a first vibration isolator disposed within the first cavity where the shaft extends through the first vibration isolator so as to capture the first vibration isolator within the first cavity where the first vibration isolator interfaces with the frame second end; and a second vibration isolator disposed on the shaft, where the shaft extends through the second vibration isolator so as to capture the second vibration isolator on the shaft where the second vibration isolator interfaces with the frame second end opposite the first vibration isolator, where the first vibration isolator and the second vibration isolator act only in compression.

A downhole tool for dampening vibrational, lateral, compressive, and tensile forces exerted on sensor equipment inside a drillstring is described. The downhole tool is housed inside the drill string. The tool generally includes a bottom end shaft for connection to the drillstring and that is telescopically engaged within a compression housing and a torsional housing. The torsional housing enables the bottom end shaft to slide axially with respect to the torsional housing whilst preventing torsional movement of the bottom end shaft relative to the torsional housing. The compression housing is connected to the sensor equipment and operatively contains a first spring between the compression housing and the bottom end shaft that absorbs compression forces between bottom end shaft and compression housing.

A tie rod assembly which includes a first rod member and an enclosure which defines an opening and contains a fluid with the first rod member affixed to the enclosure. A second rod member extends through the opening with a seal member positioned between the second rod member and the enclosure. The assembly also includes a head member affixed to the second rod member wherein the head member is positioned within the enclosure and the head member and the second rod member are moveable relative to the enclosure.

A second inner member and a second insulator are provided in a second ring-shaped member forming a torque rod. A first bore section and a second bore section are provided in front of and in the rear of the second inner member. The insulator has an elastic arm section extending in the direction of a Y axis. A spring adjustment recess extends in a slit shape in the direction of an X axis from an end of the first bore section. The spring adjustment recess forms an unrestricted part of the elastic arm section by the second ring-shaped member, whereby the Z spring in the axial direction of the inner member is lowered, and the XZ spring ratio can be changed greatly while maintaining the size of the X spring in the main vibration inputting direction.