Spa nozzle with variable cross-section inertance loops assembly and method

We claim: 1 . A nozzle assembly capable of producing a oscillating spray jet with variable oscillation frequencies depending upon fluid pressure, the assembly comprising: a fluidic geometry, formed in a flat surface of a planar body, having an inlet admitting pressurized fluid, at least one power nozzle, at least one interaction chamber, and a pair of inertance ports communicating with the fluidic geometry; a housing containing the planar body; and an inertance loop comprising a tube fluidically connecting the pair of inertance ports, said tube having a variable diameter so that a midpoint along an internal section of the tube is positioned between the pair of inertance ports, said midpoint having a smaller cross-sectional diameter in comparison to the diameter at each of the pair of inertance ports; and wherein the inertance loop is: i) attached to a major facing of the housing so as to direct flow within the inertance loop in a plane that is parallel to the flat surface, and ii) contained within a footprint of the major facing. 2 . The assembly of claim 1 wherein the fluidic geometry accommodates a first pair of inertance ports connected by the inertance loop and a second pair of inertance ports, said second pair of inertance ports connected to a second inertance loop having a different configuration in comparison to the first inertance loop. 3 . The assembly of claim 2 wherein the different configuration of the second inertance loop consists of a tube having a constant diameter. 4 . The assembly of claim 3 wherein the tube of the second inertance loop has a different length in comparison to the tube of the first inertance loop. 5 . The assembly of claim 2 wherein the different configuration of the second inertance loop consists of a tube having a different length in comparison to the tube of the first inertance loop. 6 . The assembly of claim 2 wherein the different configuration of the second inertance loop consists of a tube having a different cross sectional internal area in comparison to the tube of the first inertance loop. 7 . The assembly of claim 6 wherein the first and second inertance loops are configured to selectively allow ambient fluid communication with the pressurized fluid so as to change a frequency of oscillation in the fluid passing through the outlet. 8 . The assembly of claim 7 wherein the fluidic geometry is a single stage fluidic oscillator. 9 . The assembly of claim 2 wherein the tubes of both of the first and second inertance loops are attached to the housing. 10 . A method of controlling the frequency of oscillation in a fluidic circuit, the method comprising: providing a fluid having a preselected pressure to the inlet of a fluidic circuit, said fluidic circuit including ports to two separate inertance loops; configuring each of the two separate inertance loops a different total cross-sectional area along a length of each of said two separate inertance loops; and adjusting the preselected pressure of the fluid so as change a frequency of oscillation of fluid dispensed from an outlet of the fluidic circuit. 11 . The method of claim 10 wherein the length of each of said two separate inertance loops is identical. 12 . A fluidic circuit producing an oscillating spray, said oscillating spray having a frequency that changes in response to fluid pressure provided to the circuit, the circuit comprising: an inlet feeding fluid to a circuit; a power nozzle disposed in the circuit downstream of the inlet; a first inertance loop disposed in the circuit having a first pair of communication ports positioned on opposing sidewalls, wherein the first inertance loop is downstream of the inlet and includes a first tube connecting the first pair of communication port so that the first tube has a variable diameter; a first interaction chamber positioned adjacent to the first pair of communication ports; an outlet positioned downstream of the first interaction chamber, said outlet dispensing an oscillating spray of the fluid at a frequency that changes in response to fluid pressure provided to the inlet; and a second inertance loop disposed in the circuit having a second pair of communication ports positioned on opposing sidewalls, wherein the second inertance loop is upstream from the first pair of communication ports and includes a second tube connecting the second pair of communication ports, and wherein a total cross sectional surface area along the length of the second tube is different than a corresponding total cross sectional surface area along the length of the first tube. 13 . The circuit of claim 12 further a second interaction chamber interposed between second pair of communication ports and the first pair of communication ports. 14 . The circuit of claim 12 wherein the first tube and the second tube have identical lengths. 15 . The circuit of claim 14 wherein the first tube and the second tube have an identical number of turns. 16 . The assembly of claim 1 wherein the inertance loop contains at least three separate 180° bends. 17 . The assembly of claim 1 wherein the inertance loop contains more than four separate 180° bends.