SK12252000A3 - Engine driven by low temperature gradient and method of operating the same - Google Patents

Abstract

An engine is created a anchored double-acting piston compressor (1) consisting of a chamber (23) with a piston (22), whereby above and under him is situated a intake valve (3) and a delivery valve (4). Against the double-acting piston compressor (1) is situated a double-acting piston a expander (2) consist of a chamber (24) with a piston (21) and above and under him are created holes (8) for intake working medium to a time control intake valve (5), to a safety valve (20) and to a time control delivery valve (6), which is connected by a pipe (18) with a cooler (11) and from him is working medium feed through the intake valves (3) to the chamber (23) of the double-acting piston compressor (1) and after compression is take out through the direct delivery valve (4), a intake separating valve (12) to a heater (10). Warm medium after expansion intake through a valve of heater (9) and the time control intake valve (5) to the chamber (24) of the double-acting piston compressor (1), whereby moving of piston (21) is transmitted by a rod (7) on the piston (22) of the double-acting piston compressor (1).

Description

Low-temperature slope engine and method of operation

Technical field

The invention relates to a low-temperature gradient-driven thermal engine and a method of operation thereof capable of utilizing low-temperature sources such as waste heat, heat from solar collectors, geothermal heat, compression heat, hiomass direct combustion heat, exhaust gas heat, cogeneration heat, compressor heat natural gas stations, accumulated heat from the temperature difference between day and night, consisting of a double-acting piston compressor and a double-acting expander connected to a heater and cooler.

BACKGROUND OF THE INVENTION

Existing types of thermal engines utilize higher temperature gradients, obtained mainly by combustion of fuel within the working cylinder. Such combustion releases a considerable amount of exhales and also the efficiency of internal combustion is lower. Other known engine types capable of utilizing low-temperature gradients such as Ringhom operate at atmospheric pressure, have little power and low efficiency. They are only suitable for didactic purposes.

Engines utilizing the expansion of compressed pairs of low-boiling organic working media in the Organic Rankine Cycle turbine have relatively low heat conversion efficiency and equipment production costs are high.

Known types of Stirling engines operate with higher temperature gradients, and furthermore have the disadvantage that their heat exchange surfaces are geometrically limited due to the requirement to minimize the reactive volume. A further disadvantage is that, from a constructional and technological point of view, the heat exchanger is difficult to place in the heat source.

Engines based on classical Brayton cycles based on adiabatic compression and expansion in isobaric heating and cooling have technical limitations that do not allow the use of low temperature gradients.

SUMMARY OF THE INVENTION

The above-mentioned drawbacks are largely eliminated by the low-temperature gradient motor and the method of operation according to the invention, which consists in having a fixed double-acting piston compressor consisting of a closed piston chamber on one side and a one-way intake valve located above and below and a one-way discharge valve. In contrast to the double-acting piston compressor there is a fixed double-acting piston expander formed from a closed piston chamber whose area is larger than that of the double-acting piston compressor piston, and openings for inlet and outlet of working medium to the time-controlled suction valve a pressure relief valve, to a time-controlled discharge valve that is connected via a conduit to a cooler from which the working medium, for example CO ₂ , is fed via one-way inlet valves to the double acting piston compressor chamber. After compression to a higher pressure, the working medium is discharged through a one-way discharge valve and an inlet isolation valve to the heater. The heated working medium enters the double-acting piston expander chamber through the heater outlet valve and the time-controlled valve as the volume increases. The movement of the expander piston due to the pressure differential is transmitted by the piston to the piston of the double-acting piston compressor and the reciprocating movement of the piston rod is taken from the collection point, for example by a crank mechanism by means of a connecting rod or hydraulic system.

In another embodiment, the motor driven by the low temperature gradient has an upstream regenerative exchanger whose input is connected to the output of the double-acting piston expander and the output is coupled to the radiator. The second branch of the upstream regenerative heat exchanger has an inlet connected to the unidirectional discharge valve of the double-acting piston compressor and the outlet is connected to the heater via an inlet isolation valve.

The engine driven by the low-temperature gradient and its operation is based on the fact that in the first phase the working medium is sucked into the chamber of the double-acting piston compressor through the one-way intake valve. pressure, after which the isobaric volumetric displacement of the working medium occurs through the one-way discharge valve of the double-acting piston compressor and through the inlet isolation valve. Isobaric heating of the medium from an external heat source takes place in the heater. The heated working medium is pushed isobarically through the heater outlet valve and the time-controlled suction valve, which is controlled by the manifold, into the expander chamber, causing the piston to move under pressure. After the time-controlled suction valve closes during the piston movement, the adiabatic expansion of the heated medium takes place in the chamber of the double-acting piston expander to the lower pressure. At the dead center of the piston, the time-controlled discharge valve opens and the movement of the piston produces an isobaric discharge of the expanded medium at the lower pressure. After closing the time-controlled discharge valve, adiabatic compression of the residual volume to the upper pressure occurs to reduce the pressure surges.

The extruded working medium is isobarically cooled in a cooler. After cooling, the medium is isobarically sucked into the double acting piston compressor chamber through a one-way inlet valve.

If the isobaric coefficient of volume expansion at a given temperature gradient is higher than the ratio of expanded volume to compressed volume, this causes an increase in pressure drop.

To improve the efficiency of the engine, it is advisable to cool the compressor and heat the expander. As a result, compression and expansion are closer to isothermal.

The double acting arrangement of the compressor and expander has the advantage that only the differential pressures in the axial direction are applied to the piston, the pressure chamber being connected to the environment by means of a small diameter piston rod. The piston which connects the expander piston to the compressor piston compensates for the counter-forces acting due to the difference in piston surfaces before and after the piston rod. At the same time, the piston rod provides direct transfer of linear movement from the expander to the compressor almost without loss, as the radial forces are minimal, with frictional losses only in the piston and piston rod seals. Thus, only the differential forces act on the crank mechanism. Moreover, such an arrangement has the advantage that it allows almost perfectly to separate the cold and hot working medium and the loss of heat flux through the components is minimal.

Compressed carbon dioxide CO2, which is environmentally friendly and has suitable working characteristics, is suitable as the working medium of the low temperature engine. In this medium, the lower pressure in the cooler ranges from 50 to 90 bar, the upper pressure in the heater ranges from 90 to 180 bar, or even more. The device shall be tested to a minimum of 1,5 times the working pressure. Instead of carbon dioxide as a working medium, other substances having a high specific gravity coefficient in the desired temperature range such as freon, propane, butane, acetone, toluene, benzene, ethyl alcohol, N-alkene and others can be used. However, such working media are less suitable from an ecological point of view, especially in the case of their leakage into the air due to leaks in the system, etc.

The difference from the Brayton cycle with regeneration is in the method of compressing and expanding the medium, which uses a volumetric compressor and expander with high volumetric efficiency to allow the medium to cool during compression and heat during expansion, bringing the true course of adiabatic events closer to isothermal in the working medium used. Compression and expansion Another volumetric machine is characterized by a considerably greater volumetric efficiency than a turbocompressor in conjunction with a turbine where the low volumetric efficiency of the turbocompressor and turbine also causes significant pressure drop losses. In the case of positive displacement machines, it is possible to obtain substantially higher pressure drops without the need for technical complexity and the resulting cost of the device.

BRIEF DESCRIPTION OF THE DRAWINGS

The engine driven by the low temperature gradient and its operation is explained in more detail with the aid of the figures, in which Fig. 1 schematically shows the basic construction of an engine with a double-acting piston compressor, a double-acting piston expander, heater and cooler. Fig. 2 shows a motor driven by a low temperature gradient with an added upstream regenerative heat exchanger and its longitudinal section; 3a shows graphically the opening of the time-controlled suction valve; FIG. 3b shows graphically the opening of the time-controlled discharge valve; FIG. 3c graphically illustrates the course of differential pressures in the expander cylinder; FIG. 3d shows graphically the course of differential pressures in the compressor cylinder, FIG. Fig. 4 shows a power take-off mechanism from a reciprocating piston rod through a crank mechanism by means of a connecting rod in a side section; 5 shows a mechanism for withdrawing the reciprocating piston rod power by means of a crank mechanism by means of a flywheel translation frame; and FIG. 6 schematically illustrates a reciprocating power take-off from a piston rod without a crank mechanism by means of a pendulum arm with inertia at the end with spring-loaded end positions.

DETAILED DESCRIPTION OF THE INVENTION

The motor driven by the low temperature gradient of FIG. 1 consists, on the one hand, of a fixed-acting double-acting piston compressor 1 consisting of a closed chamber 23 with a piston 22, with a one-way intake valve 3 and a one-way discharge valve 6 positioned above and below the piston 22 a piston expander 2 formed from a closed chamber 24, with a piston 21 having an area greater than that of the piston 22. Also openings 8 are provided above and below the piston 21 for supplying working medium to the time-controlled suction valve 5, to the pressure relief valve 20. a time-controlled discharge valve 6, which is connected via a conduit 18 to a cooler 11, from which working medium, for example CO2, is fed via one-way intake valves 3 to chamber 23 of a double-acting piston compressor 1 to higher t After the upper pressure has been overcome, the working medium is discharged via a one-way discharge valve 4, an inlet separating valve 12 into the heater 10, where the working medium is heated and after increasing the volume enters the heater outlet valve 9 and time-controlled valve 5 into the double-acting piston expander chamber. 2, the movement of the piston 21 caused by the pressure difference is transmitted by the piston 7 to the piston 22 of the double-action piston compressor I and the reciprocating movement of the piston 7 is taken from the collection point 19, for example by a crank mechanism 25. 4th

The motor driven by the low temperature gradient of FIG. 2 has a counter-current regeneration exchanger 13, the inlet 16 of which is connected via a duct 18 to the outlet of the expander 2 and the outlet 17 is connected to a cooler 11. the other branch of the anti-directional regeneration exchanger 13 has an inlet 14 connected to the unidirectional discharge valve the inlet isolation valve 12 and the heater 10.

V _β

The operation of the low-slope driven motor is that in the first phase of its operation, the working medium is cooled from the cooler U to the chamber 23 of the double-acting piston compressor 1 via the one-way intake valve 3. After the upper pressure has been reached, the isobaric volumetric discharge of the working medium takes place via the one-way discharge valve 4 of the double-acting piston compressor I and via the inlet separating valve 12 to the heater 10 where the isobaric heating of the medium takes place. Thereafter, the expanded isobaric medium enters through the heater outlet valve 9 and the time-controlled suction valve 5 into the double-acting piston expander 2, as a result of which the piston 21 performs movement and performs mechanical work.

Upon closing of the time-controlled suction valve 5, before reaching the dead center of the piston 21, an adiabatic expansion of the residual working medium occurs in the chamber 24 of the double-acting piston expander 2 to the lower pressure. Upon reaching the dead center and changing the direction of movement of the piston 21, the time-controlled discharge valve 6 is simultaneously opened and the working medium is isobarically discharged from the chamber 24. After closing the time-controlled valve 6, the residual volume of the working medium is adiabatically compressed and at the headland reaches the upper pressure. The extruded working medium is fed through a conduit 18 to a cooler, after the isobaric cooling of the medium, the working cycle is closed. The dead positions of the piston 21 and the compression resistances are overcome by the crank mechanism 25 with the flywheel 28 and 28, respectively. other known technical solutions.

The ratio of the volume of working medium expanded in the displacement double-acting piston expander 2 to the volume of working medium compressed in the displacement double-acting piston compressor 1 over one cycle is lower than the relative isobaric volumetric expansion of the medium at a given temperature gradient. The unexpanded volume of the working medium ensures that the pressure drop significantly increases after the low temperature drop motor starts.

The pressure drop control in the low-temperature driven motor, if necessary, is achieved by parallel connection of another double-acting piston compressor 1 or double-acting piston expander 2. For a given temperature gradient, the working medium and the pressure gradient are selected such that the isobaric volume expansion of the medium is maximized, thereby achieving a relatively low compression work and a high expansion work.

The mechanical design of the motor driven by the low temperature gradient of FIG. 1 and Operation of the low temperature gradient motor of FIG. 3a, 3b, 3c and 3d consist of a double acting piston compressor 1, whose one-way intake valves 3 and one-way discharge valves 4 on both sides of the chamber 23 of the double-acting piston compressor 1 are controlled by pressure difference and a double-acting piston expander 2 a time - controlled suction valve 5 and a time - controlled valve

the discharge valve 6 is controlled by a timing distribution. Timing of the suction valve 5 of FIG. 3a, wherein the shaded area La indicates the period of opening of the controlled suction valve 5 at the top of the chamber 24 and the shaded area Ra at the bottom thereof. In FIG. 3b is the timing of the displacement timing valve 6, where the shaded area Lb indicates the opening period of the displacement timing valve 6 at the top of the chamber 24 and Rb at the bottom thereof. The mechanical stroke of the double-acting piston expander 2 is the same as that of the double-acting piston compressor 1, but the stroke volume of the double-acting piston expander 2 is 1.3-4 times higher than the stroke volume of the double-acting piston compressor 1 depending on the temperature gradient and working medium used. In practice, this is achieved by different diameters of piston 21 and piston 22. The piston 7 mechanically directly connects the piston 22 of the double-acting piston compressor 1 and the piston 21 of the double-acting piston expander 2. At the same time, mechanical power is taken from the piston rod.

The heater 10, which is conceived as counter-current, may be formed of high-pressure tubes of circular cross-section shaped to make full use of the available heat source. The hottest part is located at the top. The working volume of the heater 10 is not theoretically limited, which makes it possible to significantly reduce the hydraulic resistance and also makes it possible to make the best use of the lowest temperature gradients. The heater 10 may also be located at a greater distance from the motor driven by the low temperature gradient, but in such a case the supply pipes must be thermally insulated.

The cooler 11 is designed to be counter-current, formed from high-pressure tubes of circular cross-section shaped to make full use of the cooling medium. The coldest part is located at the bottom. The working volume of the cooler 11 is not theoretically limited, which makes it possible to significantly reduce the hydraulic resistance and also makes it possible to make the best use of the lowest temperature gradients. The radiator U may be located at a greater distance from the motor driven by the low temperature gradient, but in such a case the supply pipes must be perfectly thermally insulated.

The counter-current regeneration exchanger 13 is used in the case of higher temperature gradients, if it is possible and desirable to recover residual heat after expansion. The upstream regenerative heat exchanger 13 must have a high temperature resistance in the direction of the temperature gradient. The design of the anti-directional regenerative heat exchanger 13 is most preferably vertical, like the tube in the tube, with the warm portion up. To increase the heat exchange capacity, several upstream regenerative exchangers 13 are connected in parallel. In case the heat and cold source is located away from the low temperature gradient motor according to the invention, the outlet line 18 of the double-action piston compressor 1 and the outlet line 18 of the double-action piston expander 2 can be positioned concentrically to form a counter-current heat exchanger.

The mechanism for transferring the movement of the piston rod 7 for rotational movement of FIG. 4, 5 and 6 are provided by a swinging connecting rod 26 which transmits forces from the piston rod 7. In FIG. 5, the connecting rod 26 is located in a translational frame 27 which connects the two halves of the piston rod 7. The flywheel 28 ensures that the positions are overcome with a negative cycle work. To increase the uniformity of operation and increase the power, a multi-piston row or star design can be used. An alternative mechanism for transferring the movement of the piston rod 7 for pivoting movement according to FIG. 6, the pivoting arm 32 has an inertial mass at the end

31. whose end positions are mechanically limited by a spring 29 or directly driven device 30. It is necessary to ensure that the natural resonant frequency of the driven device 30 is close to the working area. In practice, this can be achieved by the magnitude of the oscillating mass 31 or the length of the oscillating arm 32.

The heater 10, the radiator 11, and the anti-recovery regeneration exchanger 13 may be common to any number of pistons 21. The motor is driven by a low-temperature gradient and the method of operation allows it to operate on one set of anti-recovery regeneration exchanger IX via pressure couplings. pressure terminal to connect several independent motors driven by low temperature gradient located at different locations. In this case, the supply lines must be perfectly insulated.

The timing mechanism for controlling the time-controlled intake valves 5 and the time-controlled discharge valves 6 is mechanical e.g. movement derived from the cam respectively. with an electromechanical movement controlled by a solenoid.

For low-temperature gradient-driven engines operating with a variable temperature gradient where engine efficiency depends, it is advantageous if the timing of the double-acting piston expander 2 can be varied, thereby increasing its efficiency. For low-slope engines with fixed timing, it is possible to use a fixed timing distribution by means of a rotary valve having a speed derived from the crank mechanism 25.

The opening of the inlet time-controlled intake valves 5 and the time-controlled discharge valves 6 of the double-acting piston expander 2 is exactly at the dead center of the piston 2l ·

The closing of the time-controlled suction valves 5 of the double-acting piston expander 2 is controlled as follows.

Pressure sensors in chamber 24 and cooler Π are mounted in the low-slope motor. During the cycle, these pressures are compared. If the pressure in the chamber 24 is permanently greater than the pressure in the cooler U, the opening angle of the time-controlled suction valve decreases gradually. As soon as the pressure in the chamber 24 drops briefly below the pressure level in the cooler 11, the opening angle of the time-controlled suction valve 5 increases by about 1 °. In this way, the timing is automatically optimized during the cycle, which positively affects the efficiency of the low temperature gradient motor.

The opening of the double-acting piston expander 2 outlet valves 2 of the time-controlled suction valve 5 and the time-controlled discharge valve 6 is exactly at the top dead center of the piston 21. The closing of these double-acting piston expander 2 valves is fixed at approximately 1-4% stroke before reaching the bottom dead center. To prevent pressure surges or sudden pressure rises when the outlet valve closes early, any excess pressure is forced out by the one-way relief valve 20 into the heater 10.

Compressing a cold working medium with a relatively small specific volume requires little compression work. The expansion of the heated medium makes it possible to obtain a substantially higher cycle expansion work. The cycle power taken is the difference between the supplied expansion work and the compression work consumed. Relatively small areas of negative work must also be overcome to complete a full duty cycle. For this purpose, a small flywheel 28, respectively, is used. another pair of double-acting piston compressors 1 and a pair of double-acting piston expander 2 having a duty cycle of 90 ° rotated are used.

In the case of a high compression ratio and a lower temperature gradient, provided that the temperature at the end of the compression is approximately the same resp. higher than the temperature at the end of the expansion, an anti-return regeneration exchanger 13 is not required and the motor driven by the low temperature gradient is simplified and reduced.

Such a low-slope driven motor also operates successfully in a free-piston design, where the reciprocating movement of the piston rod 7, as shown in FIG. 6 is transmitted by the arm 32 to the oscillating mechanical system of the driven device 30 with the inertia masses 31 located at the end of the arm 32. Such a solution has the advantage of using a low temperature gradient motor in some technological applications or applications. using a low temperature motor to drive, for example, an electric generator, pump or compressor.

Instead of a double-acting piston compressor 1 and a double-acting piston expander 2, it is in principle also possible to use another type of positive displacement compressor and expander, which are mechanically interconnected, have high volumetric efficiency and are capable of working with high pressure drops.

Power control is accomplished by simply changing the amount of medium in a closed operating cycle, thereby changing the pressure drop.

The engine is started as follows.

After stopping, the motor driven by the low temperature gradient must be fixed downstream, where the time-controlled suction valve S of the double-acting piston expander 2 is open and the heater outlet valves 9 and the inlet isolation valve 12 are closed.

The heat supplied to the exchanger will increase the pressure by the required value of approx. 20%. Upon simultaneous opening of the heater outlet valve 9 and the inlet separation valve 12, the engine starts.

In the event that the heater outlet valves 9 and the inlet isolation valve 12 remain open during engine shutdown, the engine must be started by spinning the shaft from an external source of mechanical movement.

Compared to the prior art, the low-slope motor according to the invention has the following advantages.

Low-temperature gradients, which are common in nature and practically inexhaustible, such as the accumulated heat difference between day and night in the subtropical zone, are used as an energy source (fuel) for propulsion.

The engine can also operate as an internal combustion engine, allowing biomass to be used directly as fuel, while the working medium is environmentally friendly, commercially available and will not cause any environmental damage even in the event of a leak.

The engine of the proposed concept can be produced from 1 kW up to several MW, where efficiency is increased in engines driven by low-temperature gradient with high output.

Simple, high-efficiency and low-cost heat exchangers allow perfect use of even the smallest temperature gradients.

The engine can be designed for virtually any speed, according to technological requirements, for example from 60 rpm to 20 000 rpm.

The engine output may be rotary or rectilinear, excluding the crank mechanism.

The cost of engine production is relatively low. Technological modesty allows engine production in developing countries as well.

The engine operates in a double-acting design, the pistons are designed to thermally separate the hot and cold parts from each other, thereby reducing heat loss through heat transfer.

Instead of carbon dioxide as a working medium, other substances with a high specific gravity coefficient can also be used in the desired temperature range, for example, freon, propane, butane, acetone, toluene, benzene, ethyl alcohol, and others.

It is also possible to design with a sealed crankcase, thereby reducing the number of seals per rotary seal.

The system allows for convenient and simple construction of multi-cylinder engines, whose operation is more even.

Industrial applicability of the invention

The low temperature gradient motor and the method of its operation according to the invention can be used wherever the sources of low-potential heat are for example geothermal heat, heat from direct or diffuse solar radiation, compressor heat, flue gas heat in compressor stations of natural gas. and night, in the subtropical zone and desert areas, chimney heat and the like. The obtained mechanical work can be used, for example, for cheap and environmentally friendly production of electricity or for direct drive of technical equipment, for driving pumps for irrigation, for propulsion of ships and wherever any heat sources with secured low-temperature gradients can be used.

The use of such a motor is suitable in the temperature range from 20 ° C to 400 ° C.

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Claims (3)

A low-slope driven motor and method of operation, characterized in that it has a fixed-acting double-acting piston compressor (1) consisting of a closed chamber (23) with a piston (22), located above and below it a one-way intake valve (3) and a one-way discharge valve (4), opposite to the double-acting piston compressor (1), is a fixed double-acting piston expander (2) formed from a closed chamber (24) with piston (21). (22), wherein above and below the piston (21) are provided openings (8) for supplying the working medium to the time-controlled suction valve (S), to the pressure relief valve (20), to the time-controlled discharge valve (6) which is a pipe (18) connected to a cooler (11), from which the working medium, for example CO2, is fed via one-way intake valves (3) to the chamber (23) of the double-acting piston compressor (1) and after compression to the higher pressure is discharged via a one-way discharge valve (4), an inlet separation valve (12) to the heater (10), further heated working medium enters the heater outlet (9) and the time-controlled valve (5) into the chamber (24) ) of a double-acting piston expander (2), wherein the movement of the piston (21) caused by the pressure difference is transmitted via the piston (7) to the piston (22) of the double-acting piston compressor (1) and withdrawn power from the reciprocating piston (7). 19), for example by means of a crank mechanism (25) by means of a connecting rod (26). Low-slope driven motor according to claim 1, characterized in that it has an anti-silent regenerative heat exchanger (13), the inlet (16) of which is connected via a pipe (18) to a time-controlled discharge valve (6) and an outlet (17). and connected to a cooler (11), the second branch of the anti-directional regenerative heat exchanger (13) having an inlet connected to the unidirectional discharge valve (4) and the outlet (15) connected via an inlet isolation valve (12) to the heater (10). Method for operating a low-slope driven motor according to claims 1 and 2, characterized in that, in the first phase of its operation, the piston (22) is isobarically sucked by the working medium from the cooler (11) into the chamber (23) of the double-acting piston compressor ( 1) through the unidirectional intake valve (3), after changing the direction of movement of the piston (22), adiabatic compression of the cold working medium occurs and when the upper pressure is reached while the piston (22) continues to stroke a piston compressor (1) and via an inlet isolation valve (12) to a heater (10) where isobaric heating of the medium from an external heat source takes place, then the expanded isobaric working medium enters through the heater outlet valve (9) and time-controlled suction valve (5) into the double-acting piston expander (2), thereby rendering the piston (21) active In the next stage, after closing the time-controlled suction valve (5) before reaching the dead center of the piston (21), an adiabatic expansion of the residual working medium to the lower pressure and after reaching the dead center occurs in the chamber (24) of the double-acting piston expander (2). and changing the direction of movement of the piston (21), the time-controlled discharge valve (6) is opened and the working medium is isobarically discharged from the chamber (24), where after closing the time-controlled discharge valve (6) near the dead center of the piston (21). 2) the residual volume of the working medium is compressed adiabatically and reaches the headland at the headland, the extruded working medium being fed via a conduit (18) to the cooler (11), after the isobaric cooling of the medium. a piston expander (2) to a volume of working medium compressed in a volume double acting the piston compressor (1) is less than the relative isobaric volumetric expansion of the medium at a given temperature gradient over one cycle, as a result of which the unexpanded volume of the working medium during the cycle causes a significant increase in pressure drop after start-up and ultimately ongoing cooling heating the double-acting piston expander (2) results in adiabatic compression and expansion approaching isothermal compression and expansion, thereby increasing the efficiency of the temodynamic cycle.