Abstract: An apparatus and method are described for effectively priming a non-electrically conductive filter for removal of solid inclusions from liquid metal. In one embodiment, the ceramic filter media is surrounded by a low frequency induction coil (1-60 Hz) with its axis aligned in the direction of the net metal flow. The coil is positioned to enhance the heating of any metal frozen onto, or in the pores of, the filter element. In one embodiment, the coil is positioned in order to generate Lorentz forces, which act to cause heated metal to impinge on the upper surface of the filter element, enhancing the priming action. Once a filter equipped with such a coil has been primed, it can be kept hot or reheated, and subsequently reused during several batch tapping sequences.

Abstract: There is provided a method for monitoring fluid flow, the method including: acquiring a pulse-echo signal from each of a plurality of spatially adjacent regions; for each of the pulse echo signals, forming a velocity spectrum; combining the plurality of velocity spectra into a composite data set which contains both spatial data and velocity data; and displaying the composite data set so as to present at least one aspect of the velocity data with at least one aspect of the spatial data. By combining both spatial and spectral velocity data into a composite data set and displaying aspects of the spatial data with aspects of the velocity data, the clinician can easily gauge in a quantitative or semi-quantitative way, both the size and velocities of fluid flows. In particular, the technique is useful for assessing valvular regurgitation jets in cardiac blood flows.