A snubber device for reducing shocks and vibrations in a downhole tool. The snubber includes a main body extending between upper and lower connector ends. The main body is defined by one or more cut-out portions. One or more elastomeric elements are held within the one or more cut-out portions. The cut-out portions provide flexibility to the main body. The elastomeric elements absorb shocks and vibrations and are conveniently replaceable when excessive wear reduces their shock and vibration absorbing capacity.

A snubber device for reducing shocks and vibrations in a downhole tool. The snubber includes a main body extending between upper and lower connector ends. The main body is defined by one or more cut-out portions. One or more elastomeric elements are held within the one or more cut-out portions. The cut-out portions provide flexibility to the main body. The elastomeric elements absorb shocks and vibrations and are conveniently replaceable when excessive wear reduces their shock and vibration absorbing capacity.

An inline shock dampener apparatus is configured to absorb energy from encountered axial shock events and subsequently release this energy in a controlled fashion. The inline shock dampener apparatus can be included, for example, as part of a measurement while drilling (“MWD”) or other downhole drilling assembly, and dampens these shock events by absorbing shock energy into an absorbing medium such as springs or elastomers and hydraulically-suppressing the recoil energy stored during the said shock event. Additionally, the inline shock dampener permits fluid to flow through an internal fluid flow path with little or no change to the internal flow path's volume, pressure, or effective flowrate.

An inline shock dampener apparatus is configured to absorb energy from encountered axial shock events and subsequently release this energy in a controlled fashion. The inline shock dampener apparatus can be included, for example, as part of a measurement while drilling (“MWD”) or other downhole drilling assembly, and dampens these shock events by absorbing shock energy into an absorbing medium such as springs or elastomers and hydraulically-suppressing the recoil energy stored during the said shock event. Additionally, the inline shock dampener permits fluid to flow through an internal fluid flow path with little or no change to the internal flow path's volume, pressure, or effective flowrate.

Systems and methods for damping vibrations of downhole systems are described. The systems include a downhole component configured to be disposed downhole and a shock-damping system at least one of on or in the downhole component, the shock-damping system configured to reduce torsional oscillations of the downhole component by imparting a selected shock to the downhole component. The selected shock is selected to generate damping of the torsional oscillations of the downhole system.

Systems and methods for damping vibrations of downhole systems are described. The systems include a downhole component configured to be disposed downhole and a shock-damping system at least one of on or in the downhole component, the shock-damping system configured to reduce torsional oscillations of the downhole component by imparting a selected shock to the downhole component. The selected shock is selected to generate damping of the torsional oscillations of the downhole system.

Embodiments disclosed herein relate to tools capable of amplifying or dampening axial forces produced by downhole equipment. More specifically, apparatus and methodologies provide a tool for imparting amplified axial loads (e.g., a hammer sub), or, in the alternative, for dampening/reducing downhole vibrations or “noise” (e.g., a suppressor sub).

Embodiments disclosed herein relate to tools capable of amplifying or dampening axial forces produced by downhole equipment. More specifically, apparatus and methodologies provide a tool for imparting amplified axial loads (e.g., a hammer sub), or, in the alternative, for dampening/reducing downhole vibrations or “noise” (e.g., a suppressor sub).

A swivel anchor of a drill string comprises a slip arrangement, comprising a slip body and at least one slip element; upper and lower connections attachable to further components, wherein the slip arrangement is rotatable about a longitudinal axis with respect to the upper and lower connections and a slip joint, comprising upper and lower components, wherein the upper and lower components may move relative to each other parallel with a longitudinal axis, between an open and closed positions, wherein in the open position a longitudinal displacement between the upper and lower components is greater than when the slip joint is in the closed position, and wherein when the slip joint is in the closed position, the swivel anchor length is less than when in the open position.

A swivel anchor of a drill string comprises a slip arrangement, comprising a slip body and at least one slip element; upper and lower connections attachable to further components, wherein the slip arrangement is rotatable about a longitudinal axis with respect to the upper and lower connections and a slip joint, comprising upper and lower components, wherein the upper and lower components may move relative to each other parallel with a longitudinal axis, between an open and closed positions, wherein in the open position a longitudinal displacement between the upper and lower components is greater than when the slip joint is in the closed position, and wherein when the slip joint is in the closed position, the swivel anchor length is less than when in the open position.