Perfect elasticity is not achievable in real-life situation, so spring stiffness is not perfectly constant. In this paper, we study the effect of modifying non-linear stiffness terms while keeping the nominal stiffness constant. We introduce three methods to design and tune linear and nonlinear elastic behavior in the context of compliant mechanisms and we present mechanical realizations. These designs are modeled using Euler-Bernoulli beam theory. Numerical simulation and experimental measurement show a good match with the theoretical model. We then present applications of our stiffness tuning methods to mechanical metamaterials, mechanical resonators, and mechanical computation
Compliant mechanisms derive some or all of their mobility from the flexibility of one or more of the...
Compliant actuators are more advantageous than stiff actuators in some circumstances, for example, u...
Structural modification methods were proved to be very useful for large structures, especially when ...
In this paper, feasibility of using pseudo-rigid-body modeling technique in examined on a simple mo...
In this paper a method is demonstrated for tuning the stiffness of building blocks for statically ba...
This paper focuses on design formulation of compliant mechanisms posed as a topology optimization pr...
Monolithic Flexure-based Compliant Mechanisms (MFCM) can functionally act as nonlinear springs by pr...
Many artifacts made by humans are designed to be strong and rigid to keep their shape by resisting d...
In this dissertation a collection of concepts to synthesise nonlinear springs is presented. Such spr...
Compliant mechanisms are joint-free monolithic substitutes for multi-membered rigid-body mechanisms....
Compliant mechanisms gain some or all of their mobility from the flexibility of their members rather...
Flexure hinges are widely used in mechanical devices, especially for micro- or even nano-scale appli...
Flexure mechanisms are commonly designed to be exactly constrained to favor determinism, though at t...
Being different from avoidance of singularity of closed-loop linkages, this paper employs the kinema...
The paper focuses on the enhanced stiffness modeling of robotic manipulators by taking into account ...
Compliant mechanisms derive some or all of their mobility from the flexibility of one or more of the...
Compliant actuators are more advantageous than stiff actuators in some circumstances, for example, u...
Structural modification methods were proved to be very useful for large structures, especially when ...
In this paper, feasibility of using pseudo-rigid-body modeling technique in examined on a simple mo...
In this paper a method is demonstrated for tuning the stiffness of building blocks for statically ba...
This paper focuses on design formulation of compliant mechanisms posed as a topology optimization pr...
Monolithic Flexure-based Compliant Mechanisms (MFCM) can functionally act as nonlinear springs by pr...
Many artifacts made by humans are designed to be strong and rigid to keep their shape by resisting d...
In this dissertation a collection of concepts to synthesise nonlinear springs is presented. Such spr...
Compliant mechanisms are joint-free monolithic substitutes for multi-membered rigid-body mechanisms....
Compliant mechanisms gain some or all of their mobility from the flexibility of their members rather...
Flexure hinges are widely used in mechanical devices, especially for micro- or even nano-scale appli...
Flexure mechanisms are commonly designed to be exactly constrained to favor determinism, though at t...
Being different from avoidance of singularity of closed-loop linkages, this paper employs the kinema...
The paper focuses on the enhanced stiffness modeling of robotic manipulators by taking into account ...
Compliant mechanisms derive some or all of their mobility from the flexibility of one or more of the...
Compliant actuators are more advantageous than stiff actuators in some circumstances, for example, u...
Structural modification methods were proved to be very useful for large structures, especially when ...