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Notes: The performance of an ultrasonic cutting device critically relies on the interaction of thecutting tool and the material to be cut. A finite element (FE) model of ultrasonic cutting isdeveloped to enable the design of the cutting blade to be influenced by the requirements of the toolmaterialinteraction and to allow cutting parameters to be estimated as an integral part of designingthe cutting blade. In this paper, an application in food processing is considered and FE models ofcutting are demonstrated for toffee; a food product which is typically sticky, highly temperaturedependent, and difficult to cut.Two different 2D coupled thermal stress FE models are considered, to simulate ultrasoniccutting. The first model utilises the debond option in ABAQUS standard and the second uses theelement erosion model in ABAQUS explicit. Both models represent a single blade ultrasoniccutting device tuned to a longitudinal mode of vibration cutting a specimen of toffee. The modelallows blade tip geometry, ultrasonic amplitude, cutting speed, frequency and cutting force to beadjusted, in particular to assess the effects of different cutting blade profiles.The validity of the model is highly dependent on the accuracy of the material data input and onthe accuracy of the friction and temperature boundary condition at the blade-material interface.Uniaxial tensile tests are conducted on specimens of toffee for a range of temperatures. Thisprovides temperature dependent stress-strain data, which characterises the material behaviour, to beincluded in the FE models. Due to the difficulty in gripping the tensile specimens in the testmachine, special grips were manufactured to allow the material to be pulled without initiatingcracks or causing the specimen to break at the grips. A Coulomb friction condition at the bladematerialinterface is estimated from experiments, which study the change in the friction coefficientdue to ultrasonic excitation of a surface, made from the same material as the blade, in contact with aspecimen of toffee. A model of heat generation at the blade-toffee interface is also included tocharacterise contact during ultrasonic cutting. The failure criterion for the debond model assumescrack propagation will occur when the stress normal to the crack surface reaches the tensile failurestress of toffee and the element erosion model uses a shear failure criterion to initiate elementremoval. The validity of the models is discussed, providing some insights into the estimation ofcontact conditions and it is shown how these models can improve design of ultrasonic cuttingdevices

Notes: The design of high power ultrasonic cutting devices is based on tuning a blade to alongitudinal mode of vibration at a low ultrasonic frequency, usually in the range 20-100 kHz. To achieve the required cutting amplitude, gain is designed into the blade via profiling. It is expected that the use of higher-gain blades could enable longitudinal-mode guillotine-type cutting of a range of materials traditionally difficult to cut using this technology. Using a conventional high-gain blade, a feasibility study of ultrasonic cutting of bone is conducted using compact tension specimens of bovine femur. Finite element (FE) models are created, based on the assumption that the ultrasonic blade causes a crack to propagate in a controlled mode 1 opening. The models are compared with the experimental data collected from ultrasonic bone cutting experiments. Although the proposed cutting mechanism is supported by thedata, the blade gain is insufficient to enable through cutting of long bone or other difficult to cut materials. Consequently, the paper examines the relationship between gain, profile, stress and nodal position for a range of ultrasonic cutting blades with increased gain

Notes: Damaging temperature effects observed during ultrasonic cutting operations are typically a result of friction between the vibrating blade and material, and combustion of debris. In order to prevent the high temperatures causing damage, the ultrasonic blade has to cut with a sufficient speed. This can be achieved either by applying a relatively high static load or by increasing the working vibration amplitude of the cutting edge, however, the result can be poor operational control and exceeding the fatigue limit of the blade, respectively. In this paper, the effect of blade tip profile is considered, particularly with reference to the influence of the cutting edge contact area on temperature under different static loading conditions. Titanium blades, with different cutting edge profiles are tested in a series of experiments that monitor cutting speed, static load, temperature around the cut site, and vibration amplitude at the cutting edge. The blades are tested cutting bovine femur and artificial bone material, and the cut surfaces are examined for signs of damage after each test. The experimental data reveal that blades with a small cutting edge contact area cut at a lower temperature, and that signs of thermal damage are less evident

Notes: Applications of power ultrasonics in engineering are growing and now encompass a widevariety of industrial processes and medical procedures. In the field of power ultrasonics, ultrasonicvibrations are used to effect a physical change in a medium. However, the mechanism by which aprocess can benefit from power ultrasonics is not common for all applications and can include oneor more of such diverse mechanisms as acoustic cavitation, heating, microfracture, surface agitationand chemical reactions. This paper presents two applications of power ultrasonics involving some ofthese different characteristics by concentrating on two case studies involving material failure(ultrasonic cutting) and acoustic cavitation (bacterial inactivation)