Drip line emitter and methods relating to same

What is claimed is: 1. An irrigation drip emitter, comprising: a first extruded tube layer defining an inlet, an outlet bath and a pressure-reducing flow channel extending between the inlet and outlet bath on an exterior surface thereof with the inlet and flow channel each having first and second ends and the second end of the inlet being connected to the first end of the flow channel, and the first end of the inlet opening to an inner lumen defined by an inner surface of the first tube layer, wherein the inlet defined by the first tube layer comprises an elongated bore formed by a protruding wall extending about a perimeter of the second inlet end and from the first end of the flow channel only so that the first inlet end extends into the inner lumen; a copper insert positioned in or connected to the outlet bath; and a second tube layer extruded over the first tube layer and the copper insert and enclosing the inlet and flow channel, the second tube layer defining an outlet in fluid communication with the outlet bath and the second end of the flow channel so that the flow channel extends between the inlet and outlet to create an emitter for converting a fluid flowing at a high flow rate in the inner lumen and at the first end of the inlet to a fluid with a low flow rate at the outlet of the emitter. 2. The irrigation drip emitter according to claim 1 wherein the copper insert is coupled to the first extruded tube layer. 3. The irrigation drip emitter according to claim 2 wherein the outlet bath includes a floor and the copper insert is secured to the floor of the outlet bath. 4. The irrigation drip emitter of claim 2 wherein the copper insert is fastened to a floor of the outlet bath of the emitter via at least one of an adhesive, screw, bolt, rivet, staple, hot weld, heat stake, pin, friction or press fit, tongue-and-groove, or mating or interlocking structures. 5. An irrigation drip emitter according to claim 1 wherein the pressure-reducing flow channel is a tortuous flow channel and the protruding wall that forms the elongated bore is a tapered annular wall that defines the emitter inlet and increases in diameter from the first inlet end to the second inlet end and assists in reducing fluid flow rate. 6. An irrigation drip emitter according to claim 1 wherein the first extruded tube layer is made of an elastomeric material capable of deflecting into the pressure-reducing flow channel in response to an increase in pressure of the fluid traveling through the inner lumen thereby reducing a cross-sectional area or volume of the flow channel as fluid pressure increases, and at least one of the inner and outer tube layers defines baffle walls that form at least a portion of the flow channel and the deflection of the elastomeric material into the flow channel further causes at least a portion of the baffle walls to move and lengthen the flow channel to compensate for increasing fluid pressure. 7. An irrigation drip emitter according to claim 6 wherein at least one of the first extruded tube and second tube layers define at least one stop or obstruction for preventing at least a portion of the inlet from completely collapsing in response to increasing fluid pressure. 8. An irrigation drip emitter according to claim 7 wherein the at least one stop or obstruction is a post extending from a surface of the at least one of the first extruded tube and second tube layers for preventing the at least a portion of the inlet from completely collapsing in response to increasing fluid pressure. 9. An irrigation drip emitter according to claim 1 wherein the first extruded tube layer is made of an elastomeric material capable of deflecting into the pressure-reducing flow channel in response to an increase in pressure of the fluid traveling through the inner lumen thereby reducing the cross-sectional area of the flow channel as fluid pressure increases, and the first extruded tube layer further defines ribs positioned proximate to the inlet for allowing the inlet to partially, but not completely, collapse in response to increasing fluid pressure in order to compensate for fluctuations in fluid pressure. 10. An irrigation drip emitter according to claim 1 wherein the pressure-reducing flow channel defined by the first extruded tube layer is recessed into the exterior surface of the first extruded tube layer. 11. An irrigation drip emitter according to claim 1 wherein the pressure-reducing flow channel defined by the first extruded tube layer is formed by a wall extending from the exterior surface of the first extruded tube layer. 12. An irrigation drip emitter according to claim 1 wherein at least a first portion of the inlet or pressure-reducing flow channel is recessed into the exterior surface of the first extruded tube layer and at least a second portion of the inlet or pressure-reducing flow channel is formed by a wall extending from the exterior surface of the first extruded tube layer. 13. An irrigation drip line comprising: a first extruded tube layer defining a plurality of inlets, outlet baths and pressure-reducing flow channels extending between each inlet and outlet bath on an exterior surface thereof with each pressure-reducing flow channel being located proximate to one of the plurality of inlets, the plurality of inlets opening to an inner lumen defined by an inner surface of the first tube layer and sized to receive pressurized fluid from the inner lumen wherein each of the plurality of inlets defined by the first tube layer include an elongated bore formed by a protruding wall extending about a perimeter of the inlet, the bore extending from one end of the pressure-reducing flow channel on one end of the elongated bore and having an opposite distal end extending into the inner lumen to draw the pressurized fluid from a region other than at a circumferential periphery of the lumen adjacent an inner surface of the first extruded tube; a plurality of copper inserts, each copper insert positioned in or connected to the plurality of outlet baths to deter roots from obstructing the flow of fluid through the emitter; a second tube layer extruded over the first tube layer and plurality of copper inserts, and enclosing the plurality of inlets, outlet baths and flow channels, the second tube layer defining a plurality of outlets with each outlet positioned adjacent to one of the proximate outlet baths and flow channels on an end of the flow channel opposite one of the plurality of inlets so that the flow channel extends between one of the plurality of inlets and one of the plurality of outlets to create an emitter for reducing the pressure and flow of the pressurized fluid received at the plurality of inlets by the time the fluid is discharged through the plurality of outlets. 14. An irrigation drip emitter according to claim 13 wherein each pressure reducing flow passage is a tortuous flow passage and the protruding wall that forms the elongated bore of each inlet forms a tapered annular wall that defines the elongated bore of each emitter inlet and increases in diameter from the distal end to the one end of the bore located proximate the pressure-reducing flow channel that assists in pressure reduction. 15. An irrigation drip emitter according to claim 14 wherein the first extruded tube layer defines a floor and opposing side walls for each of the pressure-reducing flow channels with the side walls further defining a height of the pressure-reducing flow channels when the second tube layer is extruded over the first extruded tube layer. 16. An irrigation drip emitter according to claim 1 wherein the first extrud