CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Application Serial No. 61/757,533, filed on January 28, 2013, entitled HEAVY DUTY ROOT

EXPANDER HEAT ENERGY RECOVERY, the disclosure of which is incorporated by reference herein in its entirety.

GOVERNMENT LICENSE RIGHTS

This invention was made with government support under Contract No. DE-EE0005650 awarded by the National Energy Technology Laboratory funded by the Office of Energy Efficiency & Renewable Energy of the United States Department of Energy. The government has certain rights in the invention.

TECHNICAL FIELD

The present disclosure relates to systems for recovering waste heat. More particularly, the present disclosure relates to organic Rankine cycle systems.

BACKGROUND

The Rankine cycle is a power generation cycle that converts thermal energy to mechanical work. The Rankine cycle is typically used in heat engines, and accomplishes the above conversion by bringing a working substance from a higher temperature state to a lower temperature state. The classical Rankine cycle is the fundamental thermodynamic process underlying the operation of a steam engine.

The Rankine cycle typically employs individual subsystems, such as a condenser, a fluid pump, a heat exchanger such as a boiler, and an expander turbine. The pump is frequently used to pressurize the working fluid that is received from the condenser as a liquid rather than a gas. The pressurized liquid from the pump is heated at the heat exchanger and used to drive the expander turbine so as to convert thermal energy into mechanical work. Upon exiting the expander turbine, the working fluid returns to the condenser where any remaining vapor is condensed. Thereafter, the condensed working fluid returns to the pump and the cycle is repeated.

A variation of the classical Rankine cycle is the Organic Rankine cycle (ORC), which is named for its use of an organic, high molecular mass fluid, with a liquid-vapor phase change, or boiling point, occurring at a lower temperature than the water- steam phase change. As such, in place of water and steam of the classical Rankine cycle, the working fluid in the ORC may be a solvent, such as n-pentane or toluene. The ORC working fluid allows Rankine cycle heat recovery from lower temperature sources such as biomass combustion, industrial waste heat, geothermal heat, solar ponds, etc. The low-temperature heat may then be converted into useful work, which may in turn be converted into electricity.

Further development in such Rankine cycle systems is desired.

SUMMARY

One aspect of the present disclosure relates to a closed- loop organic

Rankine cycle system including a Rankine cycle working circuit and a lubrication circuit. In certain examples, the Rankine cycle working circuit and the lubrication circuit have portions that coincide with one another. In certain examples, the Rankine cycle working circuit and the lubrication circuit share a common hydraulic pump. In certain examples, lubricant from the lubrication circuit and working fluid from the

Rankine cycle working circuit are allowed to mix with each other. In certain examples, the lubrication circuit is a cooling circuit that cools lubricant used to lubricate components (e.g. bearings, timing gears, etc.) of a mechanical expander that extracts energy/work from the Rankine cycle working circuit. In certain examples, lubricant from the lubrication circuit mixes with working fluid of the Rankine cycle working circuit and provides lubrication to a hydraulic pump that drives flow through both the Rankine cycle working circuit and the lubrication circuit.

Aspects of the present disclosure allow for a simplified Rankine cycle system having reduced sealing considerations and reduced pumping components. In certain examples, a separator is used to separate lubricant from the Rankine cycle working fluid before the Rankine cycle working fluid is evaporated at a heat exchanger. In certain examples, the Rankine cycle system is used to re-capture energy from waste heat from a prime mover such as an internal combustion engine, a fuel cell, or a similar component. In certain examples, Rankine cycle system is used to re-capture energy from waste heat from the prime mover of a vehicle.

A variety of additional aspects will be set forth in the description that follows. These aspects can relate to individual features and to combinations of features. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the broad concepts upon which the embodiments disclosed herein are based.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic depiction of a Rankine cycle system employing a Rankine cycle working circuit and a lubrication circuit having features that are examples of inventive aspects in accordance with the principles of the present disclosure;

FIG. 2 is a diagram depicting the Rankine cycle employed by the system shown in FIG. 1;

FIG. 3 is a cross-sectional view of a Roots-style expanders suitable for use in extracting mechanical energy from the system of FIG. 1;

FIG. 4 is a schematic depiction of the Roots-style expander of FIG. 3;

FIG. 5 is a cross-sectional view showing timing gears of the Roots-style expander of FIG. 3;

FIG. 6 is depicts an example configuration for a separator that can be used in the Rankine cycle system of FIG. 1; and

FIG. 7 schematically depicts a vehicle including a Rankine cycle system in accordance with the principles of the present disclosure. DETAILED DESCRIPTION

Referring to the drawings wherein like reference numbers correspond to like or similar components throughout the several figures.

The present disclosure relates generally to a Rankine cycle system (e.g., an organic Rankine cycle system) that utilizes heat from a heat source to generate useful work. In one example, the heat source is waste heat from a device such as a prime mover (e.g., an internal combustion engine such as a diesel engine or spark ignition engine, a fuel cell, etc.). In one example, a mechanical device, such as a rotary expander, is used to extract mechanical energy from the Rankine cycle system. In one example, the Rankine cycle system is an organic Rankine cycle system that heats the Rankine cycle working fluid (e.g., a solvent such as ethanol, n-pentane, toluene or other solvents) to temperatures that can equal or exceed 275 degrees Celsius (C).

Such high temperatures can deteriorate the lubricating oil used to lubricate moving components (e.g., bearings, gears, etc.) of mechanical devices (e.g., rotary expanders) used to extract energy from the Rankine cycle circuit. In this regard, with respect to flowable lubricating oils, it is desirable to use a lubrication cooling circuit that maintains the lubricant at acceptable temperatures. Grease typically is not effective because the solvent forming the Rankine cycle working fluid can cause de- greasing. Furthermore, grease will deteriorate at high temperatures. Lubricating oils can present issues when ineffective sealing (e.g., at mechanical components such as expanders, pumps or other components with moving parts that require lubrication) allows such oils to mix with the Rankine cycle working fluid. For example, lubricant within the Rankine cycle working fluid can be detrimental to the evaporation process by fouling the evaporator coils.

Aspects of the present disclosure relate to a closed-loop organic Rankine cycle system including a Rankine cycle working circuit and a lubrication circuit. In certain examples, the Rankine cycle working circuit and the lubrication circuit are configured such that lubricant from the lubrication circuit intentionally mixes with the Rankine cycle working fluid. In this way, the Rankine cycle working circuit and the lubrication circuit have portions that coincide with one another. In certain examples, the Rankine cycle working circuit and the lubrication circuit share a common hydraulic pump. In certain examples, the lubricant and the Rankine cycle working fluid mix at a location upstream from a low pressure side of the pump, and a separator separates the Rankine cycle working fluid from the lubricant at a location between a high pressure side of the pump and an evaporator. In certain examples, the lubrication circuit is a cooling circuit that cools lubricant used to lubricate components (e.g. bearings, timing gears, etc.) of a mechanical expander that extracts energy/work from the Rankine cycle working circuit, and lubricant from the lubrication circuit mixes with working fluid of the Rankine cycle working circuit and provides lubrication to a hydraulic pump that drives flow through both the Rankine cycle working circuit and the lubrication circuit. The mixing of the lubricant with the condensed cooled working fluid removes the heat energy from the lubricant which was captured during expander component lubrication. In certain examples, the Rankine cycle system is used to capture energy from waste heat.

FIG. 1 illustrates an organic Rankine cycle system 100 in accordance with the principles of the present disclosure. The organic Rankine cycle system 100 is configured to convert heat energy from a heat source, such as an engine 116, into mechanical energy. The organic Rankine cycle system 100 is configured to cycle a Rankine cycle working fluid (e.g., a solvent such as ethanol, n-pentane, toluene or other solvents) repeatedly through a closed-loop organic Rankine cycle. As depicted at FIG. 1, the organic Rankine cycle system 100 includes a Rankine cycle working circuit 102 having a condensing zone 104, a heating zone 106, and a mechanical energy extracting zone 108. A hydraulic pump 110 is used to move the working fluid through the Rankine cycle circuit 102. The pump 110 includes a low pressure side 112 in fluid communication with the condensing zone 104 and a high pressure side 114 in fluid communication with the heating zone 106. The mechanical energy extracting zone 108 has an inlet side 116 in fluid communication with the heating zone 106 and an outlet side 118 in fluid communication with the condensing zone 104.

The Rankine cycle system 100 also includes a lubrication circuit 113 for cycling/circulating and cooling lubricant (e.g., castor oil, synthetic oil, other oils or lubricating material) used to lubricate moving parts associated with a mechanical component (e.g., a rotary expander) of the mechanical energy extracting zone 108. The Rankine cycle working circuit 102 and the lubrication circuit 113 include a shared segment 115 in which the Rankine cycle working fluid and the lubricant are mixed with each other. The Rankine cycle working circuit 102 and the lubrication circuit 113 are co-extensive along the shared segment 115. The pump 110 is positioned along the shared segment 115 such that the mixture of Rankine cycle working fluid and lubricant flows through the pump 110 from the low pressure side 112 to the high pressure side 114. The lubricant within the mixture assists in lubricating the pump 110. The pump 110 provides positive pressure for cycling flow through both the Rankine cycle working circuit 102 and the lubrication circuit 113. The shared segment 115 starts at a primary mixing location 111 located between the condensing zone 104 and the low pressure side 112 of the pump 1 10 and extends from the primary mixing location 111, through the pump 110 to a fluid separator 119. Lubricant can be metered into the Rankine cycle working fluid at the primary mixing location 111.

The fluid separator 119 is configured to separate the lubricant from the Rankine cycle working fluid. The Rankine cycle working circuit 102 includes a nonshared segment 121 that includes Rankine cycle working fluid without lubricant. The non-shared segment 121 extends from the separator 119, through the heating zone 106, the mechanical energy extracting zone 108, and the condensing zone 104. The lubrication circuit 113 includes a non- shared segment 123 that extends from the separator 119 to the mechanical energy extracting zone 108. In one example, the nonshared segment 123 includes lubricant without Rankine cycle working fluid. At the mechanical energy extracting zone 108, the lubricant can flow through lubricant containing structures 125 such as bearings, bearing chambers, and gear chambers of a rotary mechanical expander 127. From the lubricant containment structures 125 of the mechanical energy extracting zone 108, the lubricant can flow to the primary mixing location 111 via segment 129. In certain examples, Rankine cycle working fluid can leak past the shaft seals of expander 127 into the lubricant containment structures 125 such that the segment 129 carries a mixture of lubricant and Rankine cycle working fluid. In this example, the leakage of Rankine cycle working fluid into the lubrication circuit 113 at the mechanical expander 127 does not pose an issue for the system because of the ability to subsequently separate the lubricant from the Rankine cycle working fluid. Thus, special sealing used to absolutely prevent leakage is not needed thereby reducing the quantity and/or expense of the seals in the system.

In one example, the fluid separator 119 separates the Rankine cycle working fluid from the lubricant and directs the Rankine cycle working fluid to the non- shared segment 121 and the lubricant to the non- shared segment 123. Pressure from the pump 110 drives flow of the Rankine cycle working fluid through the non-shared segment 121 and also drives flow of lubricant through the non- shared segment 123. The mechanical expander 127 can include a rotor chamber 128 containing one or more rotors. In use, the heated Rankine cycle working fluid from the heating zone 106 flows through the rotor chamber 128 of the mechanical expander 127 causing rotation of the rotors such that useful work is extracted from the Rankine cycle circuit 102. For example, work can be extracted via an output shaft 400. At the rotary mechanical expander 127, some Rankine cycle working fluid may flow across seals from rotor chamber 128 to the lubricant containment structures 125. Thus, in some examples, a mixture of Rankine cycle working fluid and lubricant flows from the lubricant containment structures 125 through segment 129 to the primary mixing location 111. Rankine cycle working fluid also flows from the mechanical expander 127 through the condensing zone 104 to the primary mixing zone 111. At the primary mixing zone 111, primary mixing between the lubricant and the Rankine cycle working fluid occurs. The mixture of Rankine cycle working fluid and lubricant flows through the pump 110 to the separator 119. The lubricant mixed with the Rankine cycle working fluid can assist in lubricating the pump 110. Heat will transfer from the heated lubricant to the cooled working fluid during the mixing process reducing the lubricant temperature to that of the cooled working fluid temperature.

In the depicted example, the Rankine cycle system 100 is configured to recapture waste energy from a prime mover, such as an engine 116 (e.g., an internal combustion engine such as a diesel or spark ignition engine or a fuel cell), by drawing waste heat from the engine (e.g., by drawing heat from the engine exhaust such as from a main exhaust line and/or from exhaust in an exhaust gas recirculation line). As depicted at FIG. 1, the heating zone 106 of the organic Rankine cycle system 100 includes at least one heat exchanger 150 for drawing waste heat from the engine 116. The heat exchanger 150 transfers heat from the engine 116 to the Rankine cycle working fluid of the Rankine cycle circuit 102 as the working fluid passes through the heating zone 106 thereby heating and evaporating the working fluid. In certain examples, the working fluid is super-heated. In other examples, the working fluid is not super-heated.

It will be appreciated that the engine 116 can be used to power a vehicle 300 (see FIG. 7). The vehicle 300 can include a torque transfer arrangement 302 (e.g., a drive train, drive shaft, transmission, differential, etc.) for transferring torque from the engine crankshaft to one or more axles 304 of the vehicle 300. The axles 304 can be coupled to wheels, tracks or other structures adapted to contact the ground. In such examples, the organic Rankine cycle system 100 and the engine 116 are carried with a vehicle chassis/frame 306 (shown schematically). In certain examples, prime movers such as fuel cells diesel engines or spark ignition engines can be used to power the vehicle.

Mechanical Energy Extraction/Recovery Device

As described above, the organic Rankine cycle system 100 of FIG. 1 includes a mechanical energy extraction zone 108 including at least one mechanical device (e.g., a reaction turbine, a piston engine, a scroll expander, a screw-type expander, a Roots expanders, etc.) capable of outputting mechanical energy from the Rankine cycle working circuit 102. In certain examples, the mechanical device relies upon the kinetic energy, temperature/heat and pressure of the working fluid to rotate the output shaft 400 (see FIG. 1). Where the mechanical device is used in an expansion application, such as with a Rankine cycle, energy is extracted from the working fluid via fluid expansion. In such instances, the mechanical device may be referred to as an expander or expansion device. However, it is to be understood that the mechanical device is not limited to applications where a working fluid is expanded across the device. In certain examples, the mechanical device includes one or more rotary elements (e.g., turbines, blades, rotors, etc.) that are rotated by the working fluid of the Rankine cycle so as to drive rotation of the output shaft 400 of the mechanical device.

In certain examples, the output shaft 400 can be coupled to an alternator used to generate electricity, used to power active components, or used to charge a battery suitable for providing electrical power on demand. In other examples, the output shaft 400 can be coupled to a hydraulic pump used to generate hydraulic pressure, used to power active hydraulic components, or used to charge a hydraulic accumulator suitable for providing hydraulic pressure on demand. In still other examples, the output shaft 400 can be mechanically coupled (e.g., by gears, belts, chains or other structures) to other active components or back to a prime mover that is the source of waste heat for the Rankine cycle system.

In one example, the mechanical device used at the mechanical energy extracting zone 108 can include a Roots-style rotary device referred to herein as a Roots-style expander. The pressure at the inlet side of the device is greater than the pressure at the outlet side of the device. The pressure drop between the inlet and outlet drives rotation within the device. Typically, except for decompression related to fluid leakage and device inefficiencies, expansion/decompression does not occur within the device itself, but instead occurs as the working fluid exits the device at the outlet. The device can be referred to a volumetric device since the device has a fixed displacement for each rotation of a rotor within the device.

FIGS. 3-5 depict a Roots-style expander 200 suitable for use at the mechanical energy extraction zone 108 of the Rankine cycle system 100. The expander 200 includes a housing 202 having an inlet 204 and an outlet 206. In use, the inlet 204 is in fluid communication with the heating zone 106 of the Rankine cycle system 100 and the outlet 206 is in fluid communication with the condensing zone 104 of the Rankine cycle system 100.

The expander housing 202 defines an internal cavity 208 (i.e., a rotor chamber) that provides fluid communication between the inlet 204 and the outlet 206. The internal cavity 208 is formed by first and second parallel rotor bores 210 (see FIG. 4) defined by cylindrical bore -defining surfaces 222. The expander 200 also includes first and second rotors 212 respectively mounted in the first and second rotor bores 210. Each of the rotors 212 includes a plurality of lobes 214 mounted on a shaft 216. The shafts 216 are parallel to one another and are rotatably mounted relative to the expander housing 202 by bearings 217 (FIG. 3). The shafts 216 are free to rotate relative to the housing 202 about parallel axes of rotation 213. The lobes 214 of the first and second rotors 212 intermesh/interleave with one another. Intermeshing timing gears 218 (see FIG. 5) are provided on the shafts 216 so as to synchronize the rotation of the first and second rotors 212 such that the lobes 214 of the first and second rotors 212 do not contact one another in use. In certain examples, the lobes 214 can be twisted or helically disposed along the lengths of the shafts 216. The rotors 212 define fluid transfer volumes 219 (FIG. 4) between the lobes 214. The lobes 214 can include outer tips 220 (FIG. 4) that pass in close proximity to the bore-defining surfaces 222 of the housing 202 as the rotors 212 rotate about their respective axes 213. In certain embodiments, the outer tips 220 do not contact the bore-defining surfaces 222.

In use of the expander 200, working fluid (e.g., vaporized working fluid or two- phase working fluid) from the heating zone 106 enters the expander housing 202 through the inlet 204. Upon passing through the inlet 204, the vaporized working fluid enters one of the fluid transfer volumes 219 defined between the lobes 214 of one of the rotors 212. The pressure differential across the expander 200 causes the working fluid to turn the rotor 212 about its axis of rotation 213 such that the fluid transfer volume 219 containing the vaporized working fluid moves circumferentially around the bore-defining surface 222 from the inlet 204 to the outlet 206. As the rotors 212 are rotated by the working fluid, mechanical energy is transferred out from the expander 200 through the output shaft 400 which coincides with one of the shafts 216. The output shaft 400 (FIG. 3) extends outwardly beyond an outer boundary of the expander housing 202 so as to be accessible for transferring torque/energy from the expander 200.

It will be appreciated that working fluid from the inlet 204 enters the internal cavity 208 of the housing 202 (see arrows 228 at FIG. 4) at a central region CR of the internal cavity 208 that is between parallel planes P, which include the axes 213 and which extend between inlet and outlet sides of the expander housing 202. The working fluid from the inlet 204 enters fluid transfer volumes 219 of the rotors 212 at the central region CR and causes the rotors 212 to rotate in opposite directions about their respective axes 213. The rotors 212 are rotated about their respective axes 213 such that the fluid transfer volumes 219 containing the working fluid move away from the central region CR along their respective circumferential bore-defining surface 222 of the housing 202 to outer regions OR (i.e., regions outside the planes P) of the internal cavity 208 as indicated by arrows 230 (see FIG. 4). The rotors 212 continue to rotate about their respective axes 213 thereby moving the fluid transfer volumes 219 from the outer regions OR back to the central region CR adjacent the outlet 206 as indicated by arrows 232. The working fluid from the fluid transfer volumes 219 exits the expander housing 202 through the outlet 206 as indicated by arrows 234 (see FIG. 4).

The intermeshing gears 218 and bearings 217 can be positioned within a lubrication chamber 402 containing lubricant for lubricating the gears 218 and the bearings 217 (see FIG. 3). The lubrication chamber 402 is an example of the lubricant containing structure 125 of FIG. 1. The temperature in the rotor cavity can be as high as 300°C to 350°C and thus bearings and timing gears in the expander are exposed to relatively high temperatures. The high temperature can deteriorate the lubricating oil for the bearings and timing gears and reduce the life of the bearings and timing gears. To prevent this from occurring, the lubrication circuit 113 can be used to circulate the lubricant through the lubrication chamber 402 so the lubricant is exposed to the high temperatures for only a limited amount of time. The lubricant of the lubrication circuit 113 is cooled when the lubricant mixes with the relatively cool Rankine cycle working fluid that exits the condensing zone 104. The cooled lubricant flows back to the lubrication chamber 402 through the non- shared segment 123 of the lubrication circuit 113. It will be appreciated that the lubrication chamber 402 is one example of a lubricant containment structure 125 and that other lubricant containing structures 125 (e.g., other lubricant chambers) can also be provided as part of the lubrication circuit 113.

Rankine Cycle Operation

FIG. 2 shows a diagram depicting a representative Rankine cycle applicable to the system 100, as described with respect to FIG. 1. The diagram depicts different stages of the Rankine cycle showing temperature in Celsius plotted against entropy "S", wherein entropy is defined as energy in kilojoules divided by temperature in Kelvin and further divided by a kilogram of mass (kJ/kg*K). The Rankine cycle shown in FIG. 2 is specifically a closed-loop Organic Rankine Cycle (ORC) that may use an organic, high molecular mass working fluid with a liquid-vapor phase change or boiling point occurring at a lower temperature than the water-steam phase change of the classical Rankine cycle. Accordingly, in the system 100, the working fluid may be a solvent, such as ethanol, n-pentane or toluene.

In the diagram of FIG. 2, the term "Q" represents the heat flow to or from the system 100, and is typically expressed in energy per unit time. The term " " represents mechanical power consumed by or provided to the system 100, and is also typically expressed in energy per unit time. As may be additionally seen from FIG. 2, there are four distinct processes or stages 142-1, 142-2, 142-3, and 142-4 in the ORC. During stage 142-1, the Rankine cycle working fluid in the form of a wet vapor enters and passes through at least one condenser at the condensing zone 104, in which the Rankine cycle working fluid is condensed at a constant temperature to become a saturated liquid. Following stage 142-1, the Rankine cycle working fluid is pumped from low to high pressure by the pump 106 during the stage 142-2. During stage 142-2, the Rankine cycle working fluid is in a liquid state.

From stage 142-2 the Rankine cycle working fluid is transferred to stage 142-3. During stage 142-3, the pressurized Rankine cycle working fluid enters and passes through the heat exchanger 150 where it is heated at constant pressure by an external heat source to become a vapor or a two-phase fluid, (i.e., liquid together with vapor). During stage 142-4, the Rankine cycle working fluid, in the form of a fully vaporized fluid or a two-phase fluid, passes through the mechanical energy extracting zone 108, thereby generating useful work or power. The working fluid may expand at the outlet of the mechanical energy extracting zone 108 thereby decreasing the temperature and pressure of the working fluid such that some additional condensation of the working fluid may occur. Following stage 142-4, the working fluid is returned to the condensing zone 104, at which point the cycle completes and will typically restart at stage 142-1. Separator

FIG. 6 shows an example separator 500 suitable for use as the separator 119 of the Rankine cycle system of FIG. 1. The separator 500 includes a separator housing 520 defining an inlet 522, a first outlet 524, and a second outlet 526. When incorporated into the Rankine cycle system 100 of FIG. 1, the inlet 522 is coupled in fluid communication with the high pressure side of the pump 110 so as to receive the mixture of lubricant and Rankine cycle working fluid from the pump 110. Also, the first outlet 524 is coupled to the first non-shared segment 121 and the second outlet 526 is coupled to the second non-shared segment 123. The separator 500 includes a porous media 527 (e.g., a filtering media, a separating media, a precipitating media) contained within the housing 520.

The porous media can include substance that contains pores or spaces between solid material through which liquid or gas can pass. Examples of naturally occurring porous media include sand, soil, and some types of stone, such as pumice and sandstone. Sponges, ceramics, and reticulated foam are also manufactured for use as porous media. It is to be understood that the type of porous media may vary with other examples. In some examples, the porous media can be made from wire mesh or knitted wire mesh, such as stainless steel wire mesh with a coiled construction, which is well suited for separating out the lubricating oil droplets. In one example, the density of the porous media can be on the order of about nine pounds per cubic foot. In other examples, the porous media can be made from a combined or co-knit metal wire and fiberglass mesh, such as a 304 stainless steel mesh co-knitted with fiberglass. These materials are found to be well-suited for filtering the lubricating oil and the porous media can have a density of about twelve pounds per cubic foot.

In this example, the mixture of lubricant (e.g., oil) and Rankine cycle working fluid (e.g., ethanol) can enter the oil separator 500 at the inlet 522 and flow through the porous media 527. The porous media 527 can slow the flow of the mixture, which encourages separation. In certain examples, the lubricant is heavier than the Rankine cycle working fluid and this weight difference allows the separator 500 to separate the lubricant from the Rankine cycle working fluid via gravity. For example within the housing 520, the lubricant sinks relative to the Rankine cycle working fluid. Thus, the Rankine cycle working fluid collects at a top 528 of the housing 520 and the lubricant collects at a bottom 530 of the housing 520. The first outlet 524 is positioned at the top 528 of the housing 520 so as to receive the separated Rankine cycle working fluid while the second outlet 526 is positioned at a bottom 530 of the housing 520 so as to receive the separated lubricant. The Rankine cycle working fluid exits the housing 520 through the first outlet 524 and flows through the first non-shared segment 121 to the heat exchanger 150. The lubricant exits the housing 520 through the second outlet 526 and flows through the second non-shared segment 123 to the lubricant containment structure 125 of the mechanical expander 127.

From the forgoing detailed description, it will be evident that modifications and variations can be made without departing from the spirit and scope of the disclosure.