RU2056606C1 - Heat energy-to-mechanical work converter - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: heat energy-to- mechanical work converter uses hermetically sealed casing 1 in the form of truncated cone partially filled with heat-transfer agent. The casing has evaporation (2) and condensation (3) regions, and an adiabatic section. The casing accommodates heat-insulating ring 4, being a component of the casing and rigidly fastened both to evaporation section 5 and condensation section 6 of the casing. Rigidly attached to the heat-insulating ring is turbine- wheel 7 with vanes 8 enclosed with rim 9, forming annular gap 10 between the heat-insulating rim and turbine-wheel rim. The turbine-wheel is provided with journal 11 that carries another turbine-wheel 12 with guide vanes 13 enclosed with rim 14, forming annular gap 15. The rim of the second turbine-wheel represents an internal annular magnet. Intsalled above the internal annular magnet is external annular magnet 16 rigidly coupled to foundation 17. The rims of both turbine-wheels have annular grooves. On the side of the evaporation region the turbine-wheel rim is furnished with additional vanes. EFFECT: improved design. 3 cl, 6 dwg

Description

 The invention relates to mechanical engineering and can be used, for example, as an engine of an aircraft.

 A device is known for converting thermal energy into mechanical operation of a Stirling engine.

 The disadvantages of the known device include a complex structure due to the presence of a rhombic mechanism that transmits movement from two pistons with complex kinematics of mutual motion to the power take-off shaft.

 As a prototype, a heat pipe was selected that converts thermal energy into electrical energy.

 The disadvantages of the prototype device include the design complexity due to the presence of a pump for pumping the coolant from the condensation zone to the evaporation zone.

 The second disadvantage of the known device is the long chain of transformations of one type of energy into another, at the end of which is a thermo-emf. This circumstance characterizes the extremely low effective efficiency of the installation as a whole.

 The aim of the invention is to simplify the design and increase the efficiency of the thermal energy Converter.

 This is achieved by the fact that the converter of thermal energy into mechanical work, working according to the Rankine cycle, contains an evaporator, a condenser, a heat engine located between the condenser and the evaporator, and a pump for pumping condensate in the liquid phase from the condenser to the evaporator.

 According to the invention, the converter of thermal energy into mechanical work comprises a sealed housing filled with a coolant with an evaporation, transport and condensation zone, a multi-stage turbine with rotor blades mounted on a disk rigidly connected to the transport zone, and a guide apparatus, rim, two ring magnets, a turbine axle, foundation and additional blades, the rim being rigidly fixed to the working blades, a gap is formed between the outer surface of the rim and the inner surface of the body, the blades are directed the washing apparatus is mounted on a disk mounted on the turbine axle with the possibility of rotation, one of the ring magnets covers the vanes of the guide apparatus and is installed with a gap relative to the casing, and the second ring magnet is mounted coaxially with the first with a gap relative to the outer surface of the casing and is fixed to the foundation, while the housing is made in the form of a truncated cone, at the base of which an evaporation zone is located, and is mounted for rotation.

 To prevent heat from flowing from the evaporation zone to the condensation zone along the converter housing due to the phenomenon of thermal conductivity, part of the transport zone in which the turbine is installed is made of heat-insulating material.

 During operation of the converter, the coolant in the evaporation zone, under the action of continuously supplied heat energy, evaporates and enters the working blades of the turbine, as a result of which the converter housing receives rotational motion. Passing through the vanes of the guide vane, the coolant is cooled in the condensation zone, goes into the liquid phase and is deposited on the walls of the housing of the thermal energy converter.

Due to the rotation of the transducer housing, and also taking into account the fact that the transducer housing is made in the form of a truncated cone, an axial force F ₂ directed towards the evaporation zone, which can be determined by the formula
F ₂ m ω ² r · sin α where F is the axial force;
m is the mass of the coolant particle in the liquid phase, ω is the angular velocity of rotation of the converter housing;
r radius of the transducer housing in the transport zone;
α angle of taper of the transmitter housing.

 In the transport zone, in the gap between the converter housing and the rim of the turbine impeller, as well as the rim of the guide vane, countercurrent flows of the coolant in the vapor state from the evaporation zone to the condensation zone and the coolant in the liquid phase from the condensation zone to the evaporation zone arise. In this case, the heat transfer fluid in the form of a film is adjacent to the transducer housing, and the heat transfer fluid in the vapor state is located between the film and the impeller rim and the guide rim.

 To create gas-dynamic resistance to the coolant flow in the vapor state from the evaporation zone to the condensation zone according to the invention, annular grooves are provided on the rims of the turbine impeller and the rims of the guide apparatus, which perform the functions of a labyrinth seal.

 To create local rarefaction in the zone of liquid coolant entering the evaporator according to the invention, additional blades are made on the rim of the working blades from the base side.

 The purpose of the two ring magnets is to transmit the momentum from the rotation of the turbine impellers and the converter housing to the foundation or body of the aircraft.

 Figure 1 presents the Converter of thermal energy into mechanical work, a General view; figure 2 heat-insulating ring, which is part of the transducer housing, fragments of the turbine blades and the guide apparatus, rims with labyrinth seals, as well as additional blades of the turbine impellers; in Fig.3 a section aa in Fig.1 (impeller of a turbine with vanes, a trunnion and a heat-insulating ring); figure 4 section BB in figure 1; figure 5 is a view along arrow B in figure 1; Fig.6 vectors of forces acting on a particle of liquid transferred from the condensation zone to the evaporation zone.

 As an example, a converter of thermal energy into mechanical work with a single-stage turbine is presented.

 The converter of thermal energy into mechanical work comprises a sealed housing 1 in the form of a truncated cone, partially filled with coolant, mounted for rotation around a longitudinal axis. The converter housing contains an evaporative 2 and a condensation 3 zone. The casing contains a heat-insulating ring 4, which is an element of the casing and is rigidly fixed both with the evaporation section 5 and with the condensation section 6 of the casing.

 A turbine impeller 7 with impellers 8 covered by a rim 9 is rigidly attached to the heat-insulating ring with the formation of an annular gap 10 between the heat-insulating ring and the impeller rim. The turbine impeller is equipped with a pin 11 on which a second turbine wheel 12 is mounted with guide vanes 13 enclosed by the rim 14 to form an annular gap 15. The rim of the second turbine wheel is an internal ring magnet. An outer ring magnet 16 is mounted above the inner ring magnet and is rigidly connected to the foundation 17. The rims of the impeller and the turbine’s additional wheel contain annular grooves 18. The rim of the turbine’s impeller on the evaporation zone side is provided with additional vanes 19.

 The Converter of thermal energy into mechanical work is as follows.

 When heat is supplied to the evaporation section 5 and heat is removed from the condensation section 6 of the housing 1, the coolant in the evaporation zone 2 passes from a liquid to a vapor state and, under pressure, enters the working blades 8 of the impeller 7 of the turbine. After that, the coolant passes through the guide vanes 13 of the second turbine wheel 12 and enters the condensation zone 3 of the converter. Having given part of the heat in the condenser 6, the coolant goes into the liquid phase and is deposited on the walls of the housing 1 of the Converter. Since the second turbine wheel 12 through two ring magnets 14 and 16 is fixed from rotation with respect to the foundation 17, the impeller 7 receives rotation together with the converter housing 1.

The coolant in the liquid phase deposited on the walls of the condensing section 6, under the action of the axial component of the force F ₂ directed toward the evaporation zone 2 passes the annular gaps 15 and 10 and into the vaporization zone converter 2, where it is evaporated again.

 In order to avoid disruption of the coolant flow in the liquid phase in the transport section, the annular grooves 18 of the rims 9 and 14 of the wheels 7 and 12 create additional gas-dynamic resistance to the movement of the oncoming coolant flow in the vapor state through the ring gaps 10 and 15, and the additional blades 19 create a vacuum at the coolant inlet section to the evaporation zone 2.

 In the proposed technical solution, all four elements of the heat engine, i.e., an evaporator, a condenser, an energy converter (turbine) and a pump, are enclosed in one sealed enclosure, which determines the simplicity of the design and the reliability of the proposed converter.

 The thermal energy converter can operate in any orientation in space.

 Almost any fuel, including solar energy, can serve as a source of converter energy.

 Scopes of the converter: on-board power supply in spacecraft; aircraft engine; stationary engines of high power.

 In real conditions, the converter turbine should be multi-stage 3-5 steps.

Claims (3)

 1. A HEAT ENERGY CONVERTER IN MECHANICAL WORK, comprising a sealed enclosure partially filled with coolant, with evaporation, transport and condensation zones, a steam turbine with rotor blades mounted on a disk, rigidly connected to the transport zone, and a guiding apparatus, characterized in that it additionally contains a rim, two ring magnets, a pin of the turbine, a foundation, the rim being rigidly attached to the working blades, a gap is formed between the outer surface of the rim and the inner surface of the housing, the blades the guide apparatus is mounted on a disk mounted on the turbine axle with the possibility of rotation, one of the ring magnets covers the vanes of the guide apparatus and is installed with a gap relative to the casing, and the second ring magnet is mounted coaxially with the first with a gap relative to the outer surface of the casing and is fixed to the foundation, while the casing is made in the form of a truncated cone, at the base of which there is an evaporation zone, and mounted for rotation, part of the transport zone in which the turbine is installed, ying of thermally insulating material.  2. The Converter according to claim 1, characterized in that on the rim of the working blades of the turbine from the side of the evaporation zone, additional blades are installed.  3. The Converter according to claim 1, characterized in that on the outer surfaces of the rim and the annular magnet covering the vanes of the guide apparatus, annular grooves are made.

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