LT5488B - The device and method for converting of thermal energy - Google Patents

Abstract

The invention is described to the field of thermal and hydraulic machines. In the device, thermal energy is converted into rotary or translation, or swing motion mechanical energy, witch is used for getting the effective work. The device is new because it is consisting of conditionally separated two or more systems for energy converting, which is connected in one unit by general roll. The energy converting system consists of: energy converters, hydraulic spreaders with piston locking and controlling device, elements for taking over the energy which by hydraulic lines through hydraulic machine is connected into total conditionally separated system of energy converting. In the energy converting system energy converter is new because of inside being conductor and isolator. In the invention is presented the method of converting thermal energy into mechanical energy and it is differs from the analogues because in one process the heat energy is converted in liquid float energy and the liquid float energ

Description

TECHNICAL FIELD OF INVENTION

The invention relates to the field of thermal and hydraulic machines. The device converts heat energy into fluid flow energy and fluid flow energy is converted into rotational and / or movable and / or oscillatory motion mechanical energy, which is used to obtain useful work-technical result.

State of the art

No direct analogues can be given to describe the essential features of the device and the energy conversion method therein. The unit combines two types of equipment that exist in practice: thermal machines and hydraulic drives. In the presented device, these two types are combined into one common and interdependent system where the systems, components, "help" each other to create useful work (technical result). Therefore, it is appropriate to compare the individual parts of the device with its counterparts.

Thermal machines (energy converters) - prior to the invention, various external combustion engines and devices are known. For example, regenerative engine, heat engine, free piston engine. The closest analogue of the device of the invention in the field of thermal machinery is the Stirling engine (Stirling, UK, 1816) (Encyclopedia of Technology, Vol. Vilnius, 2003, p. 307), which converts externally supplied fuel combustion heat into mechanical work. The Stirling engine consists of: a heat exchanger, a gas cylinder, a regenerator, a cooler, a purge piston and a working piston. Its cylinders usually have no connection to the environment (insulated) and heat is supplied through a heat exchanger called a "heater" and a heat transfer device called a "cooler" where the coolant flows. The Stirling engine and other similarly operating thermal machines operate in a closed regeneration cycle. In the aforesaid motors, rotary motion mechanical

-25 energy is transmitted by a diamond, crankshaft or diagonal disc mechanism, to rotate other devices and to obtain useful energy (technical result). These engines and equipment have drawbacks such as the need to cool the working fluid, the regeneration of the working gas, the auxiliary devices and mechanisms required for power transmission, and so on.

Hydraulic actuators are devices known to the present invention in which energy is exchanged and transmitted by a fluid. They have a hydraulic motor, pump, control, regulating, control and auxiliary equipment or devices and hydraulic lines (Technical Encyclopedia, Vol. II,

Vilnius 2003, p.200). Fluid flow energy is generated by motors or similar types of equipment such as a straight-line displacement hydraulic motor. The disadvantage of these hydraulic drives is that. that hydraulic actuators do not generate mechanical energy themselves, but rather that they come from other devices such as thermal machines. They only convert the resulting energy into another type of mechanical energy.

The object of the present invention is to convert thermal energy into mechanical energy by combining a thermal energy conversion system with a hydraulic system. The unit combines the thermal machine with the hydraulic machine into a single unit. This method of energy conversion and the apparatus used do not, as opposed to analogues, have a cooling system, regenerative elements, a piston-force mechanical mechanism and other similar elements. In current installations, the efficiency according to the Camot cycle efficiency calculation method is ~ 0.38, whereas in the conversion method and the device according to the invention, the theoretical efficiency can approach one unit. The proposed method and unit allows the use of any type of combustion fuel is environmentally friendly, extremely economical in small dimensions and does not require complicated maintenance.

The invention has wide potential applications. For example, it can be used to generate electricity or to provide mechanical energy for rotary (sliding, oscillating) motion, etc.

The essence of the invention

OBJECT OF THE INVENTION - HEAT CONVERTER (PM)

The PM unit is designed to convert thermal energy into mechanical energy. It differs from its counterparts in that it consists of relatively separate two and / or more power conversion systems (ECS) which are connected to a single PM unit via a common shaft. The mechanical energy generated by the PM unit is routed through a common shaft to external equipment (eg an electrical machine (generator)).

Energy conversion system (ECS) is used to convert thermal energy into positive / negative (depending on the thermodynamic process) mechanical energy. It consists of: two and / or more power transducers (ECs), one and / or more hydraulic distributors with a common and / or separate piston locking and control device, two and / or more power take-offs which are hydraulically connected via one and / or more hydraulic machines are combined into a single relatively separate ECU.

An energy converter (EC) is used to convert the heat energy into the flow energy of the working fluid and vice versa. The EC also compensates for the expansion or contraction of the physical volume of the working fluid in the ECS hydraulic system. It consists of a housing (element) of any geometric shape with mechanical holding and heat insulating properties inside the cylinder. The inside of the cylinder has a conductor and an insulator with a piston sliding inside. One end of the EC cylinder is closed and the other has a working fluid outlet / inlet which is connected by hydraulic lines to one and / or more power take-offs and one or more hydraulic distributors or, in the absence of a hydraulic distributor, to one or more hydraulic machines. The inside of the EC cylinder is divided into two cavities, which are separated by a piston. One cavity (on the closed side of the cylinder) is filled with working gas and the other (on the cylinder outlet / inlet side) is filled with working fluid. The conductor stores the amount of heat energy and performs heat exchange between the working gas inside the conductor and the working fluid. Conductor is a tubular piece with open ends that has thermal conductivity properties.

The conductor is mounted inside the EC cylinder, on the opposite side from the inlet / outlet. One side of the conductor is in contact with the inner closed end of the EC cylinder and the other rests on the insulator. The length of the conductor part and the outside diameter depend on the physical properties of the part material. The inside surface of the conductor coincides with the inside surface of the insulator and / or EC cylinder. The purpose of the insulator is to protect the working gas and the working fluid from heat exchange. The insulator is a tubular piece with open ends and no thermal conductivity. The insulator is mounted inside the EC cylinder on the side where the inlet / inlet is located and one edge of the insulator is in contact with the conductor and the other is on the inside end of the EC cylinder with the outlet / inlet. If the EC housing consists of a solid material that has heat insulating properties, the insulator may not be present. The EC body then performs the function of an insulator.

The purpose of the piston is to separate the working fluid inside the EC cylinder from the working gas both in terms of heat and physical insulator. A piston is a cylindrical part in which a gasket (sealing ring) can be inserted or fitted. The piston moves freely with respect to the geometry of the conductor and insulator and / or the EC cylinder as far as the working gas and working fluid allow.

Other ECOC elements are known devices and devices prior to the invention, but their use in the device differs from its counterparts.

Piston locking and control device - fixes the position of the piston in the EC cylinder and controls the hydraulic distributor (Hydraulics and Hydraulic Machines, Vilnius "Science" 1984, pp.211-217). The piston locking and control device consists of one or more separate parts. the design of the device does not matter to the operation of the ECU, its location (mounting) in the ECA does not matter, for example, part of the device may be inside the EC, part outside, may also be mounted on a hydraulic machine, etc. The location depends on the design of the device known to the present invention. The piston locking and control device is connected to a hydraulic divider by any type of mechanism.

Hydraulic distributor - for controlling (reversing) the working fluid flow direction

100 (Encyclopedia of Technology, Volume II, Vilnius2003, p.203). The hydraulic distributor is controlled by a piston locking and control device. Its design depends on the piston locking and control device chosen. The hydraulic distributor is connected by hydraulic lines on one side to one or more power take-offs and one or more ECs and on the other to one or more hydraulic machines.

105 If the ECS hydraulic machine regulates the working fluid flow, there may be no ECS hydraulic distributor and piston locking and control device, it is important that the position of the individual EC pistons is recorded.

Energy pickup element - for transferring heat energy to the working fluid (Šilumos technique, Vilnius "Science" 1993, p.142). Its design depends on heat

110 sources of energy (gas, liquid, solids). In a PM unit, the power take-off element consists of one or more parts. The power take-off unit of the EKS is connected by hydraulic lines on one side to one EC and on the other by one or more hydraulic distributors, or in the absence of hydraulic distributors on one or more hydraulic machines.

115 Hydraulic Machine - for converting working fluid flow energy into mechanical energy and vice versa (Technical Encyclopedia, Vol. II, Vilnius2003, p.199). This depends on the design of the hydraulic machine and the type of mechanical energy desired (rotary motion, sliding motion, oscillating motion, etc.). The design of the hydraulic machine is irrelevant to the operation of the PM unit, it is important that it is the same for everyone

120 hydraulic machines involved, working fluid flow (constant throughput). A hydraulic machine is connected by hydraulic lines on either side to one or more hydraulic distributors, without being connected to one or more EC and one or more power units.

Single Shaft - Designed to combine two or more individual ECTS into one single PM

125 units and differentiate the power generated between the individual ECUs and peripherals. Alternatively, the common shaft can lock the position of the individual EC pistons in the individual ECS. The common shaft may be a bar and / or transmission-coupling assembly of any geometric shape which transmits rotary and / or sliding and / or oscillating motion to other mechanical or similar elements while physically retaining these elements in the required position.

130 The unit's general shaft is connected to two and / or more hydraulic machine output shafts and / or similar devices and peripherals.

OBJECT OF THE INVENTION - A WAY TO CONVERT THERMAL ENERGY

The present invention provides a method for converting heat energy into mechanical energy. The method differs from its analogues in that in one process heat energy is converted into a liquid

135 flow energy and fluid flow energy are converted into two or more positive / negative mechanical energies, which are combined into one positive energy through a common shaft.

The present invention operates in a thermal energy conversion unit (PM) wherein the heat energy in the energy converter (EC) of a separate energy conversion system (ECS) is converted into working fluid flow energy and the working fluid flow energy in the ECS in one or more hydraulic machines is converted into separate positive / negative mechanical energies. The PM unit's two or more positive / negative energies (obtained in separate (opposite) ECUs) are combined into one common positive mechanical energy through a common shaft which transmits this energy to external devices.

The operation of the Energy Conversion System (ECS) is based on the pressure difference generated by the EC and the piston position affecting the flow direction of the ECU circulating working fluid relative to the individual EC. Working fluid flowing between one or more ECs and vice versa and / or working fluid flowing from one or more ECs to one or more hydraulic machines and vice versa, with the appropriate thermodynamic process, the ECU (hydraulic system) forms separate (partial) fluid flow (flow) energies. These energies are combined in one or more hydraulic machines into the total (unified) positive / negative ECS working fluid flow energy in the PM unit at the individual (opposite) ECS individual EC pistons such that in one thermodynamic process the ECU (s) are the energy supplier (s). and the other is the energy consumer (s) ie in one or more ECOC (s) energy converter, the piston is at equilibrium with the piston at the piston fixing point, and in the other (other) opposite ECC (s) energy converter, the piston is in equilibrium distribution.

The PM unit process is not influenced by the number of ECCs involved, it is important that there is at least two and the equilibrium of force distribution between the individual (opposite) ECCs in the thermal energy conversion unit (PM) is maintained.

In an energy converter (EC), the heat energy stored in the working fluid and / or obtained from the power take-off element is converted into the flow fluid energy of the working fluid During the EC conversion process, the working fluid transfers heat energy to the working gas through a conductor in the EC. The working gas expands as the piston moves (positive pressure), which gives the working fluid flow energy. The piston moves until the other (opposite) EC (and / or groups of) the same piston reaches the piston anchorage point During this period, the working gas cools down and the conductor is cooled. negative pressure) the working gas and piston move until the piston reaches the piston fixing point. The pressurized working gas warms up, conveying energy to the conductor at the same time. When the working fluid reaches the conductor surface, the working fluid transfers to the conductor its stored and / or received thermal energy. The process of converting ° LT 5488 B starts again, i.e. the working fluid transfers heat energy to the working gas through an EC conductor. The working gas expands as the piston moves into motion.

In the PM, individual ECs (and / or groups thereof) shall have a piston anchorage point (location) that fully completes / starts a temodynamic cycle The piston anchorage point (location) shall be selected from the set compression ratio (volume) of the working gas.

Two or more ECs can be involved in one ECS conversion process, it is important that the number of ECs selected is such that there is a balance of force distribution between the individual (opposite) ECs in the respective thermodynamic process.

Hydraulic Machine for Converting the Flow Energy of an Operating Fluid to an Mechanical Energy and Conversely, to a Mechanical Flow to Convert the Fluid Energy to a Working Fluid In the prior art operation, the device either draws or discharges fluid flow energy. When an actuator takes in the energy of a fluid flow and converts it into mechanical energy called a hydraulic motor. When the mechanical energy of the drive unit of the actuator is converted into a pressurized fluid flow energy called a hydraulic pump (Technical Encyclopedia, Vol. II, Vilnius2003, p.199). The operation of a hydraulic machine in an EKS (hydraulic system) differs from its analogues in that it performs the function of connecting the individual elements of the EKS operating in one thermodynamic process as a hydraulic pump in another as a hydraulic motor, i.e. converts the mechanical energy from the common shaft in one thermodynamic process into the fluid flow energy in another EC converts the fluid flow energy generated by the EC and transmitted by the hydraulic system into mechanical energy and transfers it to the common shaft. Also, if the ECS does not have a hydraulic distributor and a piston locking and control device, the hydraulic machine performs the function of fluid distribution (reversing) and piston locking.

In individual EKS (hydraulic systems) the power element consists of the working fluid. It differs from its analogues in that the working fluid simultaneously performs four functions: l) transfers to the EC the accumulated heat received from the energy pick-up unit 2) serves as a transmission element of the power received from the EC and the hydraulic machine 3) or by locking the piston in the EC position. The order of thermodynamic processes is controlled by the flow of working fluid in separate ECs. 4) reduces friction between moving parts.

A separate part of the ECS (hydraulic system) can be controlled by a hydraulic distributor and a piston locking and control device and / or a hydraulic machine and a common shaft. A hydraulic distributor is a hydraulic element known to the invention for controlling the direction of movement of fluid flow and actuators (hydraulic cylinder motors) (Technical Encyclopedia Vol. II, Vilnius2003, p.203). The hydraulic distributor and piston locking and control device divide the working fluid direction between the EKS elements. The hydraulic distributor also directs the working fluid flow in such a way that the inlet and outlet flow directions of the hydraulic machine do not change, although the working fluid flow direction changes with respect to the EC. For this reason, the shaft of the hydraulic machine and the universal shaft always rotate

210 in the direction. The piston locking and control device is a device known to the present invention that fixes the piston to position the EC and controls the hydraulic distributor. Depending on the type of control, they are divided into mechanical, electrical, electro-hydraulic, hydraulic and others. (Hydraulics and Hydraulic Machines, Vilnius Science 1984, pp. 211-217). They shift the hydraulic distributor when the piston reaches the piston anchorage point. Hydraulic distributor and / or piston

The locking and / or control unit 215 switches the PM unit on / off.

The common shaft differentiates (in appropriate thermodynamic processes) the positive mechanical energy obtained by the ECU between the peripheral device and the other ECA in which the negative mechanical energy is generated, i.e. some of the positive mechanical energy is transmitted to the ECU and some to the external device. Alternatively, the common shaft can be performed on individual ECOCs and on individual ECCs

220 EC Piston Lock Functions.

The term mentioned in the text:

Conversion is the translation or transfer of one type of energy to another type of energy, by elementary mechanical work or by heat (Fizika 1, Vilnius Science 1987, p.163-164). In the present invention, conversion is to be understood as the translation of one energy into

225 other types of energy and vice versa, depending on the thermodynamic process. The word Convert or Convert - means to convert, to interchange (Dictionary of International Words, Alma Littera, Vilnius 2001)

Description of the drawing figures

Device of the Invention The thermal machine (PM) and its operating cycles I to IV are shown in Fig. 4

2'30 (FIG. 1, FIG. 2, FIG. 3, FIG. 4).

The PM unit (one variant) consists of:

- common shaft; 2 - peripherals (eg electric machine or other type of equipment) and two EKS-1 and EKS-2 power conversion systems.

The EKS-1 consists of: a 3-energy pickup element; 4- power take-off element; 5235 hydraulic distributor; 6-way hydraulic distributor; 7-control device; 8-control unit's two signal receiving terminals; 9- Hydraulic machine; 10-contacts; 11-pin contacts; 12-EC; 13-EC; 14- outlet / inlet; 15- outlet / inlet; 16-conductor; 17-conductor; 18Piston Locking Rod; 19-piston locking rod; 20-piston 21-piston; 22 working gas; 23-working gas; 24-working fluid; 25-signal output nozzle; 26-signal output

240 nozzle.

The EKS-2 consists of: 27- a power take-off element; 28- power take-off element; 29hydraulic distributor; 30-hydraulic distributor; 31-control device; 32-control unit two signal receiving terminals; 33- hydraulic machine; 34 contacts; 35 contacts; 36-EC; 37-EC; 38- outlet / inlet; 39- outlet / inlet; 40-conductor; 41-conductor; 42piston fixing rods; 43-piston locking rod; 44-piston; 45-piston; 46 working gas; 47-working gas; 48-working fluid; 49-signal output nozzle; 50-signal output nozzle.

All PM units of the unit, which are located in the EKS-1 and EKS-2 hydraulic system, are connected via 51-tubes. Note: The brighter tubes 51 shown in the figures represent the active (circulating) flow of the working fluid.

Between the hydraulic distributor and the control of the hydraulic distributor is any type of mechanism -52 which is connected to the corresponding valves A, B, C, D.

Description of Embodiment of the Invention

Device for converting PM-heat energy

The elements of the PM device according to the invention are shown in four figures (Fig.1, Fig.2, Fig3, Fig.4). The chosen embodiment of the PM unit consists of two (or more) separate and closed energy conversion systems EKS-1 and EKS-2, which are connected to the common PM via a common shaft - 1. The power from the PM is transmitted to the external devices by the common shaft- 2 (such as an electric machine (generator) or other device of a similar or different nature). Each EKS uses two EK 12, 13 (EKS-1) and 36, 37 (EKS-2) (and more), two power take-off units 3, 4 (EKS-1) and 27, 28 ( EKS-2) (can be one or more), two hydraulic dividers 5, 6 (EKS-1) and 29, 30 (EKS-2) (can be one or more), and one hydraulic machine 9 (EKS-1) ) and 33 (EKS-2) (may be more). In the EKS-1 and EKS-2 hydraulic systems, the working fluid 24 and 48 is a force transmitting element that circulates back and forth (contacting vessels) from / to EK 10 to / from EK 11 (EKS-1) and from / to EK 34 to / from EK 35 (EKS-2) via respective hydraulic distributors 5 (EKS-1) and 29 (EKS-2), respective hydraulic machines 9 (EKS-1) and 33 (EKS-2), respectively 6 (EQF-1) and 30 (EQF-2), the corresponding power take-off elements 3,4 (EQF-1) and 27, 28 (EQF-2).

Common shaft 1 is designed to differentiate positive / negative energy between EKS-1 and EKS-2 and to transmit positive energy to an external device. It connects the two power conversion systems EKS-1 and EKS-2 through their hydraulic machines to one common PM unit and is connected together with an external unit (eg electric machine (generator)). A shaft is a rod of any geometric shape which transmits rotational motion to other mechanical elements while physically retaining these elements in the required position.

Energy conversion systems EKS-1 and EKS-2 (see Figures 1-4) are designed to convert heat energy into positive or negative (depending on the thermodynamic process) mechanical energy.

In the preferred embodiment, EKS-1 consists of:

280 -Two Energy Converters (EC) 12, 13 - for converting heat energy into working fluid flow energy. EK 12 and 13 consist of a cylindrical body (element) with a cylinder inside. The inner end of the cylinder is closed at one end and the openings 14 and 15 at the other end. The openings 14 and 15 are connected by a tube 51 to drain / flow the working fluid 24 from / to EC 12 and 13. EC 12 and 13 have a conductor 16 and 17 and a sliding piston 20 and 21 and a piston

285 locking rods 18 and 19 with contacts 10 and 11 and outlet nozzles 25 and 26. EK 12 and 13, the insulator is not available, since in the chosen embodiment the insulator function is performed by the EK 12 and 13 housing (solid material). Conductor 16 and 17, accumulates heat and conducts heat exchange between the working gas 22 and 23 inside the conductor and the working fluid

24. It is a tubular piece with open ends and has thermal conductivity properties. Conductor 16 and 17

The 290 is rigidly mounted on the ends of the EK 12 and 13 on the side where the piston fixing rods 18 and 19 are located. One side of the conductor 16 and 17 rests on the base of the inner closed end of the EK. The internal surface of the conductor coincides with the internal surface of EK 12 and 13. The length and diameter of the conductor part depend on the physical source of the part material. The cylindrical interior of EK 12 and 13 is divided into two cavities separated by piston 20 and 21. One cavity of conductor 16 and 17 and

295 on the sides 18 and 19 of the piston locking rod is filled with working gas 22 and 23 and the other working fluid 24. The piston 20 and 21 is a roll-shaped member. The piston moves freely with respect to the geometric shape of the EC, as allowed by the working gas 22 and 23 and the working fluid 24. The piston locking rod 18 and 19 - fixes the piston 20 and 21 to the EK 12 and 13. , on the opposite side from the EK 12 and 13 openings 14 and 15.

300 In the preferred embodiment, it is a cylindrical elongated piece with one end connected to the nozzles 25 and 26 (exterior of the EK) via contacts 10 and 11 and the other end is housed inside the ECU 12 and 13. The position of the bar is perpendicular to the EC backing. The length of the locking rod inside EK 12 and 13 depends on the maximum compression ratio (volume) of the working gas 22 and 23 selected. In the preferred embodiment, the piston 20 and 21 are locked in place by physical contact with the lock

305 of the rods 18 and 19. The signal received at the moment of contact, transmitted from the locking rods 18 and 19 through the contacts 11 and the nozzles 25 and 26 to the control device 7 via its nozzle 8.

- two energy pick-up members 3 and 4 for transferring heat energy to the working fluid 24. The power pick-up member 3 is located between the hydraulic distributor 5 and the EK 12.

The power take-off element 4 is located between the hydraulic distributor 6 and the EK 13. The power take-off "", LT 5488 B

The element 3 and 4 310 are connected to the hydraulic distributor 5 and 6, respectively, and to the tubes 51 of EK12 and EK 13, in which the working fluid 24 is circulated.

- two hydraulic distributors 5 and 6 for controlling the flow direction of the working fluid 24. The hydraulic distributor 5 is located between the hydraulic machine 9 and the energy collecting element 3 and the EK 12. They are interconnected by hydraulic hoses 51, which circulate

315 Working fluid 24. The hydraulic distributor 5 is controlled by the control device 7 through any mechanism 52 which pushes the valves (channels) A and B.

The hydraulic distributor 6 is located between the hydraulic machine 9 and the power take-off element 4 and EK13. They are interconnected by hydraulic tubes 51 in which the working fluid 24 circulates. The hydraulic distributor 6 is controlled by a control device 7 via any mechanism 52,

320 which pushes the valves (channels) C and D.

- a single control device 7 for converting the received signal into motion and controlling the hydraulic distributor 5 and 6 by this motion. The control device 7 has any type of transmission mechanism 52 which is connected to the valves (channels) A, B, C of the hydraulic distributor 5 and 6, D and two control nozzles 8. The nozzles 8 receive signals from their respective nozzles EK12 and EK13 25

325 and 26. The hydraulic distributor control unit 7 can switch PM on / off.

- a single hydraulic machine 9 for converting the flow energy of the working fluid into mechanical energy of rotary motion and vice versa. The hydraulic machine 9 is connected to the hydraulic manifolds 5 and 6 by hydraulic pipes 51 in which the working fluid 24 is circulated.

330 In the selected variant, the EKS-2 consists of:

- two energy converters (EC) 36, 37 - for converting heat energy into working fluid flow energy. EK 36 and 37 consist of a cylindrical body (element) with a cylinder inside. One end of the cylinder is closed at one end and openings 38 and 39 are provided at the other end. The openings 38 and 39 are connected by a tube 51 to allow working fluid 48 to flow from / to EC 36 and 37. EC 36 and 37

The inner surface of the 335 includes a conductor 40 and 41 and a sliding piston 44 and 45 and a piston fixing rod 42 and 43 with contacts 34 and 35 and an outlet nozzle 49 and 50. EK 36 and 37, the insulator is not available and 37 case (solid). Conductor 40 and 41, accumulates heat and conducts heat exchange between the working gas 46 and 47 and the working fluid inside the conductor

340 48. It is a tubular piece with open ends having thermal conductivity properties. Conductor 40 and 41 are rigidly mounted on the ends of EK 36 and 37 on the side where piston locking rods 42 and 43 are located. One side of conductor 36 and 37 rests on the base of the inner closed end of the EK. The inner surface of the conductor coincides with the inner surface of EK 36 and 37. The length and diameter of the conductor part depends on the physical properties of the part material. The cylindrical interior of the EK 36 and 37 is divided into two cavities which are separated by a piston 44 and 45. One cavity on the side of the conductor 40 and 41 and the piston retaining rod 42 and 43 is filled with working gas 46 and 47 and the other with working fluid 48. 44 and 45 are a roll-shaped detail. The piston moves freely with respect to the geometry of the EC, as allowed by the working gas 46 and 47 and the working fluid 48. The piston locking rod 42 and 43 - fixes the piston 44 and 45 in the EC 36 and 37 locking rod. , opposite to the openings 38 and 39 of EK 36 and 37. In the preferred embodiment, it is a cylindrical elongated piece having one end connected to the ends 49 and 50 (outside the EC) through contacts 34 and 35 and the other end being EK 36 and 37. inside. The position of the bar is perpendicular to the EC backing. The length of the locking rod inside the EC 36 and 37 depends on the maximum compression ratio (volume) of the working gas 46 and 47 selected. In a preferred embodiment, the piston 44 and 45 is locked upon physical contact with the locking rods 42 and 43. The signal received at the moment of contact is transmitted from the locking rods 42 and 43 via contacts 34 and 35 and the terminals 49 and 50 to its control device 31 through its nozzle 32.

two energy pick-up members 27 and 28 for transferring heat energy to the working fluid 48. The power pick-up member 27 is between the hydraulic distributor 29 and the EK 36. The power pick-up member 28 is between the hydraulic distributor 30 and the EK 37. The power pick-up member 27 and 28 are respectively connected to the hydraulic distributor 29 and 30 and to the pipes 51 and EK 36 and EK 37 in which the working fluid 48 circulates.

- two hydraulic distributors 29 and 30 for controlling the flow direction of the working fluid 48. The hydraulic distributor 29 is located between the hydraulic machine 33 and the energy pick-up member 27 and the EC 36. They are interconnected by hydraulic pipes 51 circulating working fluid 48. The hydraulic distributor 30 is controlled by a control device 31 which pushes the valves (channels) A and B.

The hydraulic distributor 30 is located between the hydraulic machine 33 and the power take-off element 28 and the EK37. They are interconnected by hydraulic tubes 51 in which the working fluid 48 circulates. The hydraulic distributor 30 is controlled by a control device 31 through any mechanism 52 which pushes the valves (channels) C and D.

- a single control device 31 for converting the received signal into motion and controlling said hydraulic distributor 29 and 30 by said motion. The control device 31 has any type of transmission mechanism 52 which is connected to the valves (channels) A, B, C of the hydraulic distributor 29 and 30, D and two control unit nozzles 32. Nozzles 32 receive signals from respective terminals 49 and 50 of EK36 and EK37, respectively. The hydraulic distributor control unit 31 can switch PM on / off.

- a single hydraulic machine 33 for converting the flow energy of the working fluid into mechanical energy of rotary motion and vice versa. Hydraulic machine 33 is coupled to hydraulic manifolds 29 and 30 via hydraulic pipes 51 in which working fluid 48 circulates.

The way to convert heat to heat

In a preferred embodiment of the device, the method of converting heat energy into mechanical energy is divided into cycles (see FIGS. 1, 2, 3, 4).

Preparatory phase of device operation:

Each ECS (hydraulic system) is filled with working fluid:

EKS-1 Working Fluid 24. EKS-2 Working Fluid 48.

Each EC is filled with working gas and working fluid:

EKS-1 EK 12 is filled with working gas 22 and working fluid 24. They are separated by a piston 20. The working gas 22 is compressed (working gas parameters Vi; Pi; Ti according to the gas state formula PV = RT; P-pressure; V-volume; T-temperature; R-constant). The piston 20 is in contact with the piston locking rod 18. The piston locking rod 18 is locked and ready to transmit a signal through the contact 10 and the nozzle 25 to the control device 7 via its nozzle 8. Position of the hydraulic distributor 5: valve A closed.

EKS-1 EK 13 is filled with working fluid 24 and working gas 23, which are separated by piston 21. The working gas 23 is expanded (working gas parameters V3; P3; T2). Position of hydraulic distributor 6: valve C closed, valve D closed.

EKS-2 EK 36 is filled with working fluid 48 and working gas 46, which is separated by piston 44. Working gas 46 is partially expanded (working gas parameters V ₂ ; P ₂ ; Ti). Position of hydraulic distributor 29: valve A open, valve B open.

EKS-2 EK 37 is filled with working fluid 48 and working gas 47, which are separated by piston 45. Working gas 47 is partially compressed (working gas parameters V ₄ ; P ₄ ; T ₂ ). Position of hydraulic distributor 30: valve C open, valve D open.

Note: The working gases 22, 23, 46, 47 in all ECs have the same number of moles in volume. In separate (opposite) EKS-1 and EKS-2 energy conversion systems, the piston positions in the individual energy converters are such that one EKS-1 energy conversion system energy converter EK 12 piston 20 at piston anchorage, the other opposite EKS-2 energy conversion system energy the transducers EK 36 and EK 37 have an equilibrium distribution of forces and have pistons 44 and 45 in their respective positions (shown in Figure 1).

We choose to start PM from cycle I (and may start from cycle one).

Cycle I (fig.l):

When PM is activated or PM I starts, the signal from the piston locking rod 18 is transmitted via pin 10 and tip 25 to control unit 7 via its tip 8. Control unit 7 receives a signal from tip 8 and displaces hydraulic distributor 5 and 6 by any type of mechanism 52. the valves (valves A and C are closed and valves B and D are opened) so that the flow of working fluid 24 from EC 12 to EC 13 flows through the hydraulic machine 9 and the energy pick-up unit 4. The direction of the working fluid from EC 12 to EC 13 is, because the pressure P of the working gas 22 in EK 12! is greater than the pressure P ₃ of the working gas 23 contained in EK 13. Due to the difference in pressure present, the piston 20 exerts a working fluid 24 on the EK 12, thereby expanding the working gas 22 to provide the working fluid with flow energy. The working fluid 24 flows out of EC 12 through outlet 14 and passes through valve 51 through valve B of hydraulic distributor 5 to hydraulic machine 9. In hydraulic machine 9, the flow energy of the fluid is converted into rotational mechanical energy, which is transmitted via a common shaft 1 to external unit 2 and For the hydraulic machine 2 33. From the hydraulic machine 9, the working fluid 24 continues to flow through valve D of the hydraulic distributor 6 and passes to the energy collecting element 4. In the energy collecting element 4, the working fluid 24 receives heat from an external energy source. The working fluid 24 brings the resulting amount of energy through the opening 15 into the EC 13. The working fluid 24, when introduced into the EC 13, pushes the piston 21 by pressing the working gas 23.

As mentioned above, the PM common shaft 1 differentiates the positive rotational mechanical energy obtained from the hydraulic machine 9 by transferring some of the energy to the EKS-2 hydraulic machine 33, and partly to the external device 2 (e.g., an electric machine or other device). The EKS-2 hydraulic machine 33 converts the resulting amount of rotational mechanical energy into the working fluid flow energy and transmits it to the working fluid 48. With the EKS-2 hydraulic distributor valves 29 and 30 closed and B and D open, hydraulic machines 33, the working fluid 48 flows from the EC 36 to the EC 37. The piston 44 in the EC 36 pushes the working fluid 48 to expand the working gas 46. The working gas 46 is expanding! lowers conductor temperature 40 Working fluid 48 flows from EC 36 to EC 37 through opening 38, conduits 51 through valve B of hydraulic distributor 29, hydraulic machine 33, valve D of hydraulic distributor 30, enters the energy collection element 28. In the energy collection element 28, the working fluid 48 receives heat energy from an external source of energy. From the energy collection element 28, the working fluid 48 passes through tubes 51, through an opening 39, into the EC 37. The working fluid 48 entering the EC 37 pushes the piston 45 by pressing the working gas 47. The pressurized working gas 47 warms up and transfers part of the heat energy to the conductor 41.

In the PM device, the conversion process takes place until the piston 45 in EK 37 reaches the piston retaining rod 43. When the piston 45 reaches the piston retaining rod 4a, a signal is received which is transmitted to the control device 31 via its contact 32 and output nozzle 50 via its nozzle 32. device 31, by pushing the hydraulic distributors 29 and 30 by any type of mechanism 52, opens valves A and C and closes B and D. As a result, the working fluid 48 begins to flow from EC 37 to EC 36. From this point, PM activity moves to Cycle II

Cycle II (Fig.2):

In the PM II cycle, the signal from the piston locking rod 43 is transmitted through the contact 35 and the nozzle 50 to the control unit 31 via its nozzle 32. The control unit 31 receives the signal from the nozzle 32 and locks the valves 29 and 30 of the hydraulic distributor 29 The C-valves are opened and the B and D valves are closed) so that the flow of working fluid 48 from EK 37 to EK 36 flows through the hydraulic machine 33 and the energy pick-up unit 27. The direction of the working fluid from EC 37 to EC 36 is because The pressure Pi of the working gas 47 in EK 37 is greater than the pressure P ₃ of the working gas 46 in EK 36. Due to the difference in pressure present, the piston 45 exerts a working fluid 48 on the EK 37. At the same time, the working gas 47 expands to provide the working fluid with flow energy. The working gas 47 expands due to the amount of heat energy received from the working fluid 48 through the conductor 41. The working gas 47 converts the amount of thermal energy obtained into useful elemental mechanical work which is passed through the piston 45 to the working fluid 48. The working fluid 48 through the opening 39 and through the tubes 51, the valve C passes through the hydraulic distributor 30 to the hydraulic machine 33. In the hydraulic machine 33, the flow energy of the fluid is converted into rotational mechanical energy which is transmitted via a common shaft 1 to auxiliary unit 2 and EKS-1 hydraulic machine 9. The working fluid 48 continues to flow through valve A of the hydraulic distributor 29 and enters the energy collection element 27. In the energy collection element 27, the working fluid 48 receives heat from an external power source. The working fluid 48 brings the resulting energy through the opening 38 into the EC 36. The working fluid 48 entering the EC 36 pushes the piston 44 by pressing the working gas 46.

As mentioned above, the PM common shaft 1 differentiates the positive rotational mechanical energy obtained from the hydraulic machine 33 by transferring part of the energy to the EKS-1 hydraulic machine 9, and partly to the external unit 2 (e.g. an electric machine or other device) performing useful work in the EKS- Hydraulic machine 9 converts the resulting amount of rotational mechanical energy into the working fluid flow energy and transmits it to the working fluid 24. With EKS-1 hydraulic distributor valves 5 and 6 closed and B and D open, hydraulic machine 9 the working fluid 24 flows from EC 12 to EC 13. The working gas 22 in the EK 12 pushes the piston 20 and the working fluid 24 as the working gas 22 expands, reducing the temperature of the conductor 16. Working fluid 24 kirsXt ^ o? Flowing from the EC 13 to the EC 13 through the opening 14, the tubes 51 pass through valve B of the hydraulic distributor 5, the hydraulic machine 9, the valve D of the hydraulic distributor 6 into the energy collection element 4. In the energy collection element 4, the working fluid 24 power source. From the energy collection element 4, the working fluid 24 passes through the tubes 51, through the opening 15, into the EC 13. The working fluid 24 entering the EC 13 pushes the piston 21 by pressing the working gas 23. The pressed working gas 23 warms up and transfers part of the heat energy to the conductor 17.

In the PM device, the conversion process continues until the piston 21 in the EK 13 reaches the piston retaining rod 19. When the piston 21 reaches the piston retaining rod 19, a signal is received which is transmitted to the control device 7 via its contact 11 and output nozzle 26 via its nozzle 8. the control unit 7 opens the valves A and C by pushing the hydraulic distributors 5 and 6 by any type of mechanism 52 and closes B and D. As a result, the working fluid 24 begins to flow from EC 13 to EC 12. From this point, PM operation moves to Cycle III.

Cycle III (Fig.3):

In the PM III cycle, the signal from the piston locking device 19 is transmitted through the contact 11 and the nozzle 26 to the control device 7 via its nozzle 8. The control device 7 receives a signal from the nozzle 8 and displaces the valves 5 and 6 of the hydraulic distributor 5 Valves C open and valves B and D) closed so that the flow of working fluid 24 from EC 13 to EC 12 flows through hydraulic machine 9 and power take-off element 3. The direction of working fluid from EC 13 to EC 12 is because EC The pressure Pi of the working gas 23 in 13 is greater than the pressure P3 of the working gas 22 in EK 12. Due to the difference in pressure present, the piston 17 exerts a working fluid 24 on the EK 13, thereby expanding the working gas 23 to provide the working fluid with flow energy. The working gas 23 expands due to the amount of heat energy received from the working fluid 24 through the conductor 17. The working gas 23 converts the amount of heat energy received into the elementary mechanical work, which is passed through the piston 17 to the working fluid 24. The working fluid 24 through the opening 15 and through the conduits 51, the valve C enters the hydraulic machine 9 through the hydraulic distributor 6. In the hydraulic machine 9, the flow energy of the fluid is converted into rotational mechanical energy which is transmitted through the common shaft 1 to the external unit 2 and the EKS-2 hydraulic machine. the working fluid 24 of the hydraulic machine 9 continues to flow through valve A of the hydraulic distributor 5 and enters the energy collecting element 3. In the energy collecting element 3, the working fluid 24 receives heat from an external energy source. The working fluid 24 brings the resulting amount of energy through the opening 14 into the EC 12. The working fluid 24 entering the EC 12 pushes the piston 20 by pressing the working gas 22.

As mentioned above, the PM common shaft 1 differentiates the positive mechanical rotational energy from the hydraulic machine 9 by transferring part of the energy to the EKS-2

520 to a hydraulic machine 33, transferring part of it to an external unit 2 (e.g., an electric machine or other device) performing useful work. The EKS-2 hydraulic machine 33 converts the resulting amount of rotational, movable mechanical energy into the working fluid flow energy and transmits it to the working fluid 48. With EKS-2 hydraulic distributor valves 29 and 30, valves A and C closed and B and D open, the hydraulic machine 33 created working fluid 48

Flow 525 flows from EC 37 to EC 36. The working gas 47 in the EC 37 pushes the piston 45 and the working fluid 48. The working gas 47 decreases the temperature of the conductor 41 as it expands. The working fluid 48 flows from the EC 37 to the EC 36 through the opening 39, through the tubes 51 through the valve C of the hydraulic distributor 30, the hydraulic machine 33, the valve A of the hydraulic distributor 29 into the energy pick-up unit 27.

530 power from an external power source. From the energy collection element 27, the working fluid 48 passes through the tubes 51, through the opening 38, into the EC 36. The working fluid 48 entering the EC 36 pushes the piston 44 by pressing the working gas 46. The pressed working gas 46 warms up and transfers part of the heat energy to the conductor 40.

In the PM unit, the conversion process continues until the piston 44 in EK 36 reaches

535, when the piston 44 reaches the piston locking rod 42, a signal is received which is transmitted via the contact 34 and the output nozzle 49 to the control device 31 via its nozzle 32. By receiving a signal, the control device 31, by displacing the hydraulic distributors 29, and 30, valves A and C close and B and D open. As a result, the working fluid 48 begins to flow from EC 36 to EC 37. From this point on, PM operation

540 proceeds to cycle IV.

* Cycle IV (Fig.4):

In the PM IV cycle, the signal from the piston locking rod 42 is transmitted via the contact 34 and the nozzle 49 to the control device 31 via its nozzle 32. The control device 31 receives the signal from the nozzle 32 and displaces the hydraulic distributor 29 and 30 by any type of mechanism 52.

545 valves (valves A and C are closed and valves B and D are opened) so that the flow of working fluid 48 from EC 36 to EC 37 flows through a hydraulic machine 33 and a power take-off element 28. The direction of the working fluid from EC 36 to EC 37 is , because the pressure Pi of the working gas 46 in the EC 36 is greater than the pressure P3 of the working gas 47 in the EC 37 Due to the difference in pressure present, the piston 44 pressures the working fluid 48 in the EK 36.

550 working fluid flow energy. The working gas 46 expands due to the amount of heat energy obtained from the working fluid 48 through the conductor 40. The working gas 46 converts the amount of thermal energy obtained into useful elementary mechanical work which is passed through the piston 44 to the working fluid 48. The working fluid 48 the opening 38 and the tubes 51 pass through the valve B of the hydraulic distributor 29 into the hydraulic

555 Machine 33. In a hydraulic machine 33, the fluid energy of the fluid is converted into mechanical energy of rotary motion, which is transmitted through the common shaft 1 to the peripheral device 2 and the EKS-1. for the hydraulic machine 9. From the hydraulic machine 33, the working fluid 48 continues to flow through the valve D of the hydraulic distributor 30 and passes to the energy collecting element 28. In the energy collecting element 28, the working fluid 48 receives heat from an external power source. Received

The working fluid 48 brings the 560 energy flow through the opening 39 into the EC 37. The working fluid 48, when introduced into the EC 37, pushes the piston 45 by pressing the working gas 47.

As mentioned above, the PM common shaft 1 differentiates the positive rotational mechanical energy from the hydraulic machine 33 by transferring part of the energy to the EKS-1 hydraulic machine 9, and partly to the external device 2 (e.g.

565 type of device) doing useful work. The EKS-1 hydraulic machine 9 converts the resulting amount of rotational mechanical energy into the working fluid flow energy and transmits it to the working fluid 24. With the EKS-1 hydraulic distributor valves 5 and 6 open and closed in B and D, hydraulic machines The working fluid 24 created in Fig. 9 flows from EK 13 to EK 12. The working gas 23 in EK 13 pushes the piston 21 and the working fluid

570 fluid 24. Working gas 23 decreases conductor temperature 17 as it expands Working fluid 24 flows from EC 13 to EC 12 through orifice 15, conduits 51 through valve C of hydraulic distributor 6, hydraulic machine 9, valve A of hydraulic distributor 5 enters the energy pickup element

3. In the energy collection element 3, the working fluid 24 receives a quantity of heat energy from an external energy source. From the energy pick-up member 3, the working fluid 24 is tubed 51 through an orifice

575 14 falls inside the EC 12. The working fluid 24, when introduced into the EC 12, pushes the piston 20 • by pressing the working gas 22. The pressurized working gas 22 warms up and transfers part of the heat energy to the conductor 16.

In the PM device, the conversion process continues until the piston 20 in EK 12 reaches the piston locking rod 18. When the piston 20 reaches the piston locking rod 18,

580 receives a signal which is conveyed via contact 10 and output nozzle 25 to control unit 7 via its nozzle 8. After receiving signal 7, control unit 7 closes valves A and C by pushing hydraulic distributors 5 and 6, and B and D opens. As a result, the working fluid 24 begins to flow from EC 12 to EC 13. From this point, PM activity moves to Cycle I ·

Claims (10)

Definition of the Invention 1.Equipment for the conversion of heat energy, consisting of an energy converter, a power take-off element (a heat machine) and a hydraulic distributor, a piston locking and control device, a hydraulic machine, hydraulic lines (hydraulic actuators) characterized in that the device consists of two or more conduits separate power conversion systems connected by a hydraulic shaft to a common shaft, each energy conversion system consisting of: - two or more power transducers, each connected by hydraulic lines on one side to a separate power take-off unit and on the other side to one hydraulic distributor; wherein each energy converter comprises a housing of any geometric shape having mechanical holding and insulating properties; a cylinder inside it, which at one end is closed and has an outlet / inlet at the other end; on the inside surface of the cylinder, on the opposite side from the inlet / inlet, between the insulator and the inside closed end of the cylinder, with a tubular, open-ended, conductive heat conductor of a certain (depending on the selected material) exchange between the working gas inside the conductor and the working fluid; on the inside surface of the cylinder between the conductor and the inner end of the cylinder having an inlet / outlet opening with a tubular shape, open ends, no heat conductivity insulator of any length, protecting the working gas and the working fluid from heat exchange; and a reciprocating piston which divides the interior of the cylinder into two cavities, one filled with working gas on the closed side of the cylinder and the other with working fluid on the outlet / inlet side of the cylinder; - two or more hydraulic distributors, each of which is connected by hydraulic lines on one side to an energy pick-up unit and an energy converter and on the other to one or more hydraulic machines; - a piston locking and control device having one piston locking device in each of the energy converters and connected to two or more hydraulic distributors in any type of mechanism; - two or more power take-offs, each of which is connected by hydraulic lines to a hydraulic distributor on the one hand and an energy converter on the other; - one or more hydraulic machines connected by hydraulic lines on one side to one or more hydraulic distributors and, on the other, to one or more hydraulic distributors; 2. The apparatus of claim 1, wherein the apparatus for converting energy into energy conversion systems comprises: - two or more energy converters, each connected by hydraulic lines on one side to a separate power take-off unit and / or one or more hydraulic machines; - two or more power take-offs, each of which is connected by hydraulic lines on one side to one or more hydraulic machines and on the other by an appropriate power converter; - one or more hydraulic machines linked by hydraulic lines to one or more power take-offs and / or one or more energy converters; 3. A device as claimed in claim 1 or 2, wherein the energy converter cylinder does not have an insulator inside each of the energy converter systems, then its function is performed by the energy converter housing. 4. A device as claimed in any of claims 1-3, wherein the piston locking and control device of each of the energy conversion systems comprises one or more piston locking devices on one or more hydraulic machines. 5. A device as claimed in any of claims 1-4, wherein the common shaft of the device is connected at one end to shafts and / or other types of hydraulic machines of the respective hydraulic conversion systems and at the other end to the other or other energy conversion systems. the shafts and / or other devices of the respective hydraulic machines and the external shaft mounted on the common shaft. 6. A method for converting heat energy into mechanical energy, wherein, in a single process, in each of the energy conversion systems, heat energy is stored in the working fluid in one of the energy converters and / or is received from the pickup by a conductor in the energy converter. transmitted to the working gas, which, upon expansion (thermodynamic process), provides the piston with a sliding motion, by which the pushed working fluid receives the flow fluid of the working fluid, which the fluid flows through the hydraulic distributor to the hydraulic machine, after receiving the amount of heat energy from the element, it enters another energy converter of the same energy conversion system and presses (thermodynamic process) the working gas until the piston reaches reaches the piston fixing point where, upon reaching the point, the hydraulic distributor reverses the direction of flow of the working fluid and, in the energy converter, the heat accumulated in the working fluid and / or received from the energy pickup is transmitted to the working gas whereby the pushed working fluid receives the flow fluid of the working fluid, which is transmitted by the working fluid through a hydraulic distributor to a hydraulic machine which converts the fluid flow energy into mechanical energy and flows further through the hydraulic distributor to recover the amount of heat energy converter and presses (thermodynamic process) working gas until the piston reaches the piston fixing point and from this point the process starts from new; the positive mechanical energy generated by one (or more) energy conversion system (s) during the process is appropriately differentiated by a common shaft between the external device and the other (or other) energy conversion system (s) in which negative mechanical energy is generated. 7. The method of claim 6, wherein the working fluid in each of the energy conversion systems of the heat energy converting device enters the respective hydraulic machine from the energy converter to the other energy converter of the same energy conversion system but returns back. 8. A method according to claim 6 or 7, characterized in that in the energy conversion system, the number of opposing energy converters is selected such that a balance of force distribution is achieved between the individual (opposite) energy converters during the respective thermodynamic process. 9. A method as claimed in any of claims 6-8, wherein in the device during the respective energy conversion process, there is a force distribution between the two (opposite) energy conversion systems in the presence of two or more energy conversion systems. 10. A method as claimed in claims 6-9, wherein the piston position of the individual (opposite) energy conversion systems in the individual energy converters is such that in one thermodynamic process the energy conversion system (s) is the energy supplier (s) and s) ie one or more energy conversion system (s) in the energy converter with the piston at the piston fixing point, the other (s) in the opposite energy conversion system (s) energy converters having an equilibrium distribution of forces and having the corresponding pistons position.