Static mixer with a triangular mixing conduit

What is claimed: 1. A static mixer for mixing a fluid flow having at least two components, the static mixer comprising: a mixing conduit defining an inner surface that comprises a first inner surface, a second inner surface that extends from the first inner surface, and a third inner surface that extends from the first inner surface to the second inner surface, such that the first, second, and third inner surfaces define a mixing passage configured to receive the fluid flow, and the first and second inner surfaces are offset by a first acute angle, the first and third inner surfaces are offset by a second acute angle, and the second and third inner surfaces are offset by a third acute angle; and a mixing element positioned in the mixing passage and defining a substantially triangular cross-section, wherein the mixing element is configured to contact the first, second, and third inner surfaces and defines a first mixing baffle that extends from a leading edge to a trailing edge, the first mixing baffle configured to divide the fluid flow into a first portion and a second portion and the leading edge defined by a plurality of leading edge portions obliquely angled relative to each of the first, second, and third inner surfaces of the mixing conduit. 2. The static mixer of claim 1 , wherein the mixing conduit defines an outer surface comprising a first outer surface that is substantially parallel to the first inner surface, a second outer surface that is substantially parallel to the second inner surface, and a third outer surface that is substantially parallel to the third inner surface. 3. The static mixer of claim 1 , wherein the mixing conduit further comprises: a body section that defines the mixing passage; a socket connected to the body section, wherein the socket defines a socket opening in communication with the mixing passage; and a nozzle connected to the body section opposite the socket, wherein the nozzle defines an outlet in communication with the mixing passage, wherein the fluid flow is configured to flow through the socket opening, through the mixing passage, and out the outlet. 4. The static mixer of claim 3 , wherein the socket defines an inner surface that is at least partially threaded. 5. The static mixer of claim 1 , wherein the first mixing baffle includes a first mixing panel, a second mixing panel, and a third mixing panel, each of the first, second, and third mixing panels partially defining the leading edge and the trailing edge, wherein the first, second, and third mixing panels are respectively configured to divide the fluid flow into the first portion, the second portion, and a third portion. 6. The static mixer of claim 5 , wherein the first mixing baffle is configured to rotate the first, second, and third portions of the fluid flow in a first rotational direction as the fluid flow flows from the leading edge of the first mixing baffle to the trailing edge. 7. The static mixer of claim 6 , wherein the mixing element further includes a second mixing baffle integral with the first mixing baffle, the second mixing baffle extending from a leading edge to a trailing edge and including a first mixing panel, a second mixing panel, and a third mixing panel, such that the each of the first, second, and third mixing panels of the second mixing baffle partially define the leading edge and the trailing edge of the second mixing baffle, wherein the first, second, and third mixing panels of the second mixing baffle are configured to divide the fluid flow into a fourth portion, a fifth portion, and a sixth portion. 8. The static mixer of claim 7 , wherein the second mixing baffle is configured to rotate the fourth, fifth, and sixth portions in a second rotational direction that is opposite the first rotational direction as the fluid flow flows from the leading edge to the trailing edge of the second mixing baffle. 9. The static mixer of claim 5 , wherein the first mixing panel defines a first edge and a second edge, the first edge of the first mixing panel extending from the leading edge to the second edge of the first mixing panel, and the second edge of the first mixing panel extending from the first edge of the first mixing panel to the trailing edge, wherein the first edge of the first mixing panel is configured to contact the first inner surface of the mixing conduit, and the second edge of the first mixing panel is configured to contact the second inner surface of the mixing conduit. 10. The static mixer of claim 9 , wherein the second mixing panel defines a first edge and a second edge, the first edge of the second mixing panel extending from the leading edge to the second edge of the second mixing panel, and the second edge of the second mixing panel extending from the first edge of the second mixing panel to the trailing edge, wherein the first edge of the second mixing panel is configured to contact the second inner surface of the mixing conduit, and the second edge of the second mixing panel is configured to contact the third inner surface of the mixing conduit. 11. The static mixer of claim 10 , wherein the third mixing panel defines a first edge and a second edge, the first edge of the third mixing panel extending from the leading edge to the second edge of the third mixing panel, and the second edge of the third mixing panel extending from the first edge of the third mixing panel to the trailing edge, wherein the first edge of the third mixing panel is configured to contact the third inner surface of the mixing conduit, and the second edge of the third mixing panel is configured to contact the first inner surface of the mixing conduit. 12. The static mixer of claim 1 , wherein the first mixing baffle is configured to rotate the first and second portions of the fluid flow in a first rotational direction as the fluid flow flows from the leading edge to the trailing edge of the first mixing baffle. 13. The static mixer of claim 12 , wherein the mixing element defines a second mixing baffle integral with the first mixing baffle that extends from a leading edge to a trailing edge, and the second mixing baffle is configured to divide the fluid flow into a third portion and a fourth portion. 14. The static mixer of claim 13 , wherein the second mixing baffle is configured to rotate the third and fourth portions of the fluid flow in a second rotational direction that is opposite the first rotational direction as the fluid flow flows from the leading edge to the trailing edge of the second mixing baffle. 15. A method of mixing first and second components with a static mixer that includes a mixing conduit and a mixing element that includes a first mixing baffle and a second mixing baffle downstream from the first mixing baffle, the method comprising: flowing a fluid flow through a first end of a mixing passage of the mixing conduit, wherein the mixing passage defines a first inner surface, a second inner surface that extends from the first inner surface, and a third inner surface that extends from the first inner surface to the second inner surface such that the mixing passage and the mixing element is configured to contact the first, second, and third inner surfaces and defines a substantially triangular cross-section; flowing the fluid flow over a leading edge of the first mixing baffle to divide the fluid flow into at least two first portions; flowing the at least two first portions, the leading edge of the first mixing baffle defined by a plurality of leading edge portions obliquely angled relative to each of the first, second, and third inner surfaces of the mixing passage of the fluid flow along the firs