METHOD AND IMPROVED DEVICE FOR CONVERTING THERMAL ENERGY INTO KINETIC ENERGY

Abstract

The invention relates to a method for converting thermal energy, in particular energy from the environment, into kinetic energy and to a device for converting thermal energy into kinetic energy, said device being used to carry out the method. In the method according to the invention, two circuits with fluids are operatively connected together in that on at least three heat exchangers, one fluid influences the others. The two circuits are additionally provided with environmental heat exchangers which preset the temperature of the fluids being used. The exhaust heat used for this purpose can originate from the industrial sector for example.

Claims

1. A method of converting thermal energy to kinetic energy, the method comprising: in a first circuit (2): compressing a first gaseous fluid with an accompanying increase in temperature, wherein the compressing generates a pumping movement of the fluid through the first circuit (2); cooling the first fluid in a first heat exchanger (6) with condensation; further cooling the first fluid in a third heat exchanger (11) with further condensation; decompressing the first fluid in a decompression valve (7); absorbing heat in a second heat exchanger (8); and further absorbing thermal energy in a first environmental heat exchanger (4); and parallelly in a second circuit (3): pumping a second fluid through the second circuit (3); heating in a third heat exchanger (11); evaporating in a second environmental heat exchanger (12); further heating in a first heat exchanger (6); transferring the second fluid to a thermal engine (9) with associated pressure reduction and release of thermal energy; abstracting the energy in the thermal engine (9); and recycling the second fluid into the second heat exchanger (8) and liquefying the second fluid; wherein the first and second circuits (2, 3) are subject to mutual conditionality in that a condenser in one circuit is an evaporator in the other circuit.

2. The method of converting thermal energy to kinetic energy as claimed in claim 1, characterized in that there is no further condensation in the third heat exchanger (11).

3. The method of converting thermal energy to kinetic energy as claimed in claim 1, characterized in that the second fluid is already evaporated in the second environmental heat exchanger (12).

4. The method of converting thermal energy to kinetic energy as claimed in claim 1, characterized in that, at at least one point in each circuit (2, 3), the method comprises: taking one or more of temperature, flow rate, and pressure measurements; evaluating data collected; and optimizing a respective circuit by means of closed-loop controllers.

5. The method of converting thermal energy to kinetic energy as claimed in claim 1, characterized in that waste heat generated at a pump (10) in the second circuit (3) is fed to the second circuit (3) between the second environmental heat exchanger (12) and the first heat exchanger (6) or between the first heat exchanger (6) and the thermal engine (9).

6. An improved apparatus (1) for conversion of thermal energy to kinetic energy, the apparatus comprising: a first circuit (2) for fluids comprising: a first environmental heat exchanger (4), a compressor (5), a first heat exchanger (6), a decompression valve (7) and a second heat exchanger (8), wherein, in the first circuit (2), the first heat exchanger (6) serves as condenser and the second heat exchanger (8) serves as evaporator; and a second circuit (3) for fluids comprising: the first heat exchanger (6), a thermal engine (9), the second heat exchanger (8) and a pump (10), wherein, in the second circuit (3), the first heat exchanger (6) serves as evaporator and the second heat exchanger (8) serves as condenser; wherein the first and the second circuits (2, 3) are fluidically unconnected but have functional relationships in the first heat exchanger (6) and in the second heat exchanger (8), characterized in that, in the first circuit (2), a third heat exchanger (11) is disposed downstream of the first heat exchanger (6), and, in the second circuit (3), the third heat exchanger (11) and a second environmental heat exchanger (12) are disposed downstream of the pump (10), wherein, in the third heat exchanger (11), a functional relationship exists between the first circuit (2) and the second circuit (3).

7. The improved apparatus (1) for conversion of thermal energy to kinetic energy as claimed in claim 6, characterized in that the apparatus further comprises: measurement sensors for one or more of temperature, flow rate, and pressure; a control unit for processing measurement data; and closed-loop controllers for controlling the process.

8. The improved apparatus (1) for conversion of thermal energy to kinetic energy as claimed in claim 6, characterized in that the environmental heat exchangers (4, 12) are incorporated into external circuits.

9. The improved apparatus (1) for conversion of thermal energy to kinetic energy as claimed in claims 6, characterized in that the pump (10) in the second circuit (3) is configured as a compressor.

10. The improved apparatus (1) for conversion of thermal energy to kinetic energy as claimed in claims 6, characterized in that at least two of the first heat exchanger (6), the third heat exchanger (11), the second environmental heat exchanger (12) are connected in a heat exchange arrangement.

11. The improved apparatus (1) for conversion of thermal energy to kinetic energy as claimed in claims 6, characterized in that the circuits (2, 3) have bypass conduits for bypassing the environmental heat exchangers (4, 12).

12. The method of converting thermal energy to kinetic energy as claimed in claim 1, characterized in that, the apparatus comprises bypass conduits for bypassing the environmental heat exchangers (4, 12) and protect the apparatus from overheating in a controlled manner.

Description

EXECUTION OF THE INVENTION

[0038] The invention is elucidated by a working example. In this regard, FIG. 1 shows a schematic overview of the apparatus of the invention.

[0039] Two circuits 2, 3 are shown, which are in contact at multiple points. Wherever there is contact of circuits 2, 3 there is a heat exchanger 6, 8, 11 disposed. The fluids that move through the circuits 2, 3 mutually influence one another here. A compressor 5 is sufficient to achieve a flowing motion in the first circuit. The fluid from the first circuit 2 is compressed here, and its temperature is increased. There is a release of thermal energy in the first heat exchanger 6, a further release of thermal energy in the third heat exchanger 11, and decompression in the decompression valve 7.

[0040] Thereafter, fluid absorbs thermal energy first in the second heat exchanger 8 and then in the first environmental heat exchanger 4. The fluid is therefore at its highest temperature after the compression, and at its lowest after the decompression.

[0041] In the second circuit 3, a fluid is pumped by a pump in the direction of the third heat exchanger 11, where the fluid is heated. There is further heating of the fluid in the second environmental heat exchanger 12, another increase in temperature in the first heat exchanger 6, and then transfer to the thermal engine 9. The heat generates kinetic energy, which cools the fluid. The fluid is then liquefied again in the second heat exchanger 8 before being pumped back into the second circuit 3.

LIST OF REFERENCE NUMERALS

[0042] 1 apparatus [0043] 2 first circuit [0044] 3 second circuit [0045] 4 first environmental heat exchanger [0046] 5 compressor [0047] 6 first heat exchanger [0048] 7 decompression valve [0049] 8 second heat exchanger [0050] 9 thermal engine [0051] 10 pump [0052] 11 third heat exchanger [0053] 12 second environmental heat exchanger