Recirculating pump inlet

We claim: 1. A pump, comprising: a housing having a volute configured to receive a pump impeller therein; an extension tube fluidly coupled to the volute, a wall of the extension tube having an internal surface disposed opposite an external surface; and a bonnet having a second internal surface defining a first inlet aperture and a second inlet aperture therethrough, the first inlet aperture and the second inlet aperture being in fluid communication with the volute via the extension tube, the second internal surface of the bonnet and the external surface of the extension tube defining a bonnet flow path therebetween, the second inlet aperture of the bonnet being in fluid communication with the volute via the bonnet flow path, wherein the external surface of the extension tube is contiguous with the internal surface of the extension tube at an inlet end of the extension tube and includes a convex surface located near the inlet end of the extension tube, and a cylindrical surface disposed between the convex surface and the volute along a longitudinal axis of the extension tube, wherein a thickness of the wall at the convex surface is greater than a thickness of the wall at the cylindrical surface, and wherein an annular area of the bonnet flow path at a radial plane intersecting the convex surface is less than an annular area of the bonnet flow path at a radial plane intersecting the cylindrical surface, the radial plane intersecting the convex surface and the radial plane intersecting the cylindrical surface each being perpendicular to the longitudinal axis. 2. The pump according to claim 1 , wherein a longitudinal direction of the extension tube is parallel to the longitudinal axis, and wherein a longitudinal extent of the second inlet aperture lies at least partly between an inlet of the extension tube and an outlet of the extension tube along the longitudinal direction. 3. The pump according to claim 2 , wherein an entirety of the longitudinal extent of the second inlet aperture lies between the inlet of the extension tube and the outlet of the extension tube along the longitudinal direction. 4. The pump according to claim 2 , wherein a vector normal to the second inlet aperture is substantially perpendicular to the longitudinal axis. 5. The pump according to claim 1 , wherein a longitudinal direction of the extension tube is parallel to the longitudinal axis, and wherein a longitudinal extent of the extension tube lies entirely within a longitudinal extent of the second internal surface of the bonnet along the longitudinal direction. 6. The pump according to claim 1 , wherein a longitudinal direction of the extension tube is parallel to the longitudinal axis, and a vector normal to the first inlet aperture is substantially parallel to the longitudinal axis. 7. The pump according to claim 6 , wherein the vector normal to the first inlet aperture is substantially collinear with the longitudinal axis. 8. The pump according to claim 1 , wherein the external surface of the extension tube is not contiguous with the internal surface of the extension tube near an outlet end of the extension tube. 9. The pump according to claim 1 , wherein the thickness of the wall at the convex surface is at least twice as thick as the thickness of the wall at the cylindrical surface. 10. A fluid system, comprising: a pump having an inlet and an outlet; an extension tube fluidly coupled to the inlet of the pump, a wall of the extension tube having an internal surface disposed opposite an external surface; and a bonnet having a second internal surface defining a first inlet aperture and a second inlet aperture therethrough, the first inlet aperture and the second inlet aperture being in fluid communication with the inlet of the pump via the extension tube, the second internal surface of the bonnet and the external surface of the extension tube defining a bonnet flow path therebetween, the outlet of the pump being in fluid communication with the inlet of the pump via the second inlet aperture and the bonnet flow path, wherein the external surface of the extension tube is contiguous with the internal surface of the extension tube at an inlet end of the extension tube and includes a convex surface located near the inlet end of the extension tube, and a cylindrical surface disposed between the convex surface and the volute along a longitudinal axis of the extension tube, wherein a thickness of the wall at the convex surface is greater than a thickness of the wall at the cylindrical surface, and wherein an annular area of the bonnet flow path at a radial plane intersecting the convex surface is less than an annular area of the bonnet flow path at a radial plane intersecting the cylindrical surface, the radial plane intersecting the convex surface and the radial plane intersecting the cylindrical surface each being perpendicular to the longitudinal axis. 11. The fluid system of claim 10 , further comprising a fluid reservoir in fluid communication with the inlet of the pump via the first inlet aperture of the bonnet. 12. The fluid system of claim 10 , further comprising a filter having an inlet and an outlet, the inlet of the filter being in fluid communication with the outlet of the pump, and the outlet of the filter being in fluid communication with the inlet of the pump via the bonnet flow path. 13. A method for operating a fluid system, the fluid system including a pump having an inlet and an outlet; an extension tube fluidly coupled to the inlet of the pump, a wall of the extension tube having an internal surface disposed opposite an external surface, and a bonnet having a second internal surface defining a first inlet aperture and a second inlet aperture therethrough, the second internal surface of the bonnet and the external surface of the extension tube defining a bonnet flow path therebetween, wherein the external surface of the extension tube is contiguous with the internal surface of the extension tube at an inlet end of the extension tube and includes a convex surface located near the inlet end of the extension tube, and a cylindrical surface disposed between the convex surface and the volute along a longitudinal axis of the extension tube, wherein a thickness of the wall at the convex surface is greater than a thickness of the wall at the cylindrical surface, and wherein an annular area of the bonnet flow path at a radial plane intersecting the convex surface is less than an annular area of the bonnet flow path at a radial plane intersecting the cylindrical surface, the radial plane intersecting the convex surface and the radial plane intersecting the cylindrical surface each being perpendicular to the longitudinal axis; the method comprising: flowing a first fluid from the outlet of the pump to the inlet of the pump via the second inlet aperture and the bonnet flow path; flowing a second fluid from a reservoir to the inlet of the pump via the first inlet aperture; and combining the first fluid with the second fluid upstream of a volute of the pump.