Increasing accuracy of measurements using mud retorts by maximizing recovery of vapors

What is claimed is: 1. A mud retort assembly, comprising: a retort that heats a fluid and thereby generates vapors, the retort comprising a top chamber, a bottom chamber, and a plate separating the top chamber and the bottom chamber, the plate comprising an orifice that provides fluid communication between the top chamber and the bottom chamber; a condenser in fluid communication with the retort to at least partially condense the vapors and thereby generate a liquid; a condensate collector that receives the liquid and residual vapors via an outlet pipe of the condenser; a collector plug having a frustoconical body that extends at least partially into the condensate collector at an opening to the condensate collector and defining a central aperture that receives the outlet pipe, the collector plug further having an annular flange extending radially outward from the frustoconical body to rest on the condensate collector at the opening, wherein the collector plug comprises steel, brass, copper, aluminum, bronze, or alloys thereof; and a retaining ring releasably coupled to the outlet pipe to retain the collector plug on the outlet pipe. 2. The mud retort assembly of claim 1 , wherein the collector plug comprises: a first end and a second end opposite the first end; and an outer surface that tapers from the second end toward the first end and at least partially defines the frustoconical body, wherein the annular flange extends radially outward from the second end and the central aperture is defined through the frustoconical body and extends between the first and second ends. 3. The mud retort assembly of claim 1 , further comprising a sealing element that at least partially seals a clearance defined between the outlet pipe and an inner wall of the central aperture. 4. The mud retort assembly of claim 3 , wherein the sealing element rests on the second end of the frustoconical body. 5. The mud retort assembly of claim 3 , wherein the sealing element is positioned within an annular groove defined on the inner wall of the central aperture. 6. The mud retort assembly of claim 1 , wherein the retort further comprises a heating element that is adjacent to the bottom chamber. 7. The mud retort assembly of claim 1 , wherein the collector plug comprises a surface finish of about 40 micro-inches or less. 8. The mud retort assembly of claim 1 , wherein the retort further comprises a heating element that is shaped as an open cylinder and is positioned to partially enclose the retort. 9. A method, comprising: heating a fluid within a retort and thereby generating vapors from the fluid, the retort comprising a top chamber, a bottom chamber, and a plate separating the top chamber and the bottom chamber, the plate comprising an orifice that provides fluid communication between the top chamber and the bottom chamber; condensing at least a portion of the vapors into a liquid using a condenser in fluid communication with the retort; receiving the liquid and any residual vapors in a condensate collector via an outlet pipe of the condenser; and mitigating escape of the residual vapors from the condensate collector with a collector plug positioned at an opening to the condensate collector, the collector plug having a frustoconical body that extends partially into the condensate collector at the opening and defining a central aperture that receives the outlet pipe, the collector plug further having an annular flange extending radially outward from the frustoconical body to rest on the condensate collector at the opening, wherein the collector plug comprises steel, brass, copper, aluminum, bronze, or alloys thereof. 10. The method of claim 9 , wherein a clearance is defined between the outlet pipe and an inner wall of the central aperture, and the method further comprises at least partially sealing the clearance using a sealing element to reduce an amount of the residual vapors from escaping from the condensate collector. 11. The method of claim 10 , wherein at least partially sealing the clearance comprises resting the sealing element on the second end of the frustoconical body to seal the clearance. 12. The method of claim 10 , wherein at least partially sealing the clearance comprises positioning the sealing element within an annular groove defined on the inner wall of the central aperture to seal the clearance. 13. The method of claim 9 , further comprising retaining the collector plug on the outlet pipe using a retaining ring releasably coupled to the outlet pipe. 14. The method of claim 9 , further comprising preventing the liquid from sticking to the collector plug by coating the collector plug with a hydrophobic material. 15. The method of claim 9 , wherein the collector plug comprises at least one of a non-corrosive material and a material having a melting point greater than about 300° C.