A high-temperature side power piston (37) and a low-temperature side power piston (39), respectively demarcating a high-temperature space (45) and a low-temperature space (47), brings about volumetric changes of working gases in each of the high-temperature space (45) and the low-temperature space (
A high-temperature side power piston (37) and a low-temperature side power piston (39), respectively demarcating a high-temperature space (45) and a low-temperature space (47), brings about volumetric changes of working gases in each of the high-temperature space (45) and the low-temperature space (47). At the same time, the power pistons are configured to transmit motive energy on receipt of pressure changes of working gases. A displacer (203) movably housed in a displacer cylinder (201) transfers the working gases between the high-temperature space (45) and the low-temperature space (47) without causing a pressure difference.
대표청구항▼
The invention claimed is: 1. A heat engine comprising: a high-temperature space portion and a low-temperature space portion, each of which has a working gas with a different temperature range from each other; a regenerator provided between the high-temperature space portion and the low-temperature
The invention claimed is: 1. A heat engine comprising: a high-temperature space portion and a low-temperature space portion, each of which has a working gas with a different temperature range from each other; a regenerator provided between the high-temperature space portion and the low-temperature space portion; two power pistons configured to cause volumetric changes of the working gases in each of the high-temperature space portion and the low-temperature space portion, and transmit motive energy on receipt of pressure changes of the working gases; and a displacer configured to transfer the working gases between the high-temperature space portion and the low-temperature space portion, wherein: heat and motive energy are exchanged by using the change in volume of the high-temperature space portion and the change in volume of the low-temperature space portion, the spaces being located respectively on both sides of the regenerator, as well as by using the transfer of the working gases, the two power pistons are configured to move relatively to each other, and each of the two power pistons has a pressure receiving face placed opposite the regenerator. 2. The heat engine according to claim 1, further comprising a displacer housing portion: being installed adjacent to both of the high-temperature and the low-temperature space portions; communicating with each of the high-temperature and the low-temperature space portions; and housing the displacer therein as allowing the displacer to reciprocate in the housing portion. 3. A heat engine comprising: a high-temperature space portion and a low-temperature space portion, each of which has a working gas with a different temperature range from each other; a regenerator provided between the high-temperature space portion and the low-temperature space portion; two power pistons configured to cause volumetric changes of the working gases in each of the high-temperature space portion and the low-temperature space portion, and transmit motive energy on receipt of pressure changes of the working gases; and a displacer configured to transfer the working gases between the high-temperature space portion and the low-temperature space portion, wherein heat and motive energy are exchanged by using the change in volume of the high-temperature space portion and the change in volume of the low-temperature space portion, the spaces being located respectively on both sides of the regenerator, as well as by using the transfer of the working gases, and wherein the displacer includes two pistons, each of which is configured to move with a phase difference of 180° to each other, and one of the two pistons is placed in the high-temperature space portion and the other of the two pistons is placed in the low-temperature space portion. 4. The heat engine according to claim 3, wherein any one of the two power pistons and any one of the two displacers are integrated into a single unit. 5. The heat engine according to claim 4, wherein the other of the two power pistons and the other of the two displacers are provided so that the power piston and the displacer can be sealed from each other and move relatively to each other. 6. A heat engine comprising: a high-temperature space portion and a low-temperature space portion, each of which has a working gas with a different temperature range from each other; a regenerator provided between the high-temperature space portion and the low-temperature space portion; a power piston configured to cause a volumetric change of the working gas in any one of the high-temperature space portion and in the low-temperature space portion, and transmit motive energy on receipt of a pressure change of the working gas; two displacers, each of which has a larger area for receiving pressure than that of the power piston, the two displacers being placed in the respective high-temperature space portion and the low-temperature space portion, and configured to transfer the working gases between the high-temperature space portion and the low-temperature space portion; and two pistons respectively provided to the two displacers, each of which is configured to move with a 180° phase difference to each other, wherein heat and motive energy are exchanged by using the change in volume of the high-temperature space portion and the change in volume of the low-temperature space portion, one of the spaces being located on one of the sides of the regenerator and the other of the spaces being located on the other of the sides of the regenerator, as well as by using the transfer of the working gases. 7. The heat engine according to claim 1, wherein a plurality of heat engine units, each of which includes the displacer and the power piston, are stacked in the arranging direction; and the displacer or the power piston between each of the heat engine units located next to each other, is shared by each of the heat engine units located next to each other as an integrated displacer or as an integrated power piston. 8. The heat engine according to claim 6, wherein a plurality of heat engine units, each of which includes the displacer and the power piston, are stacked in the arranging direction; and the displacer or the power piston between each of the heat engine units located next to each other, is shared by each of the heat engine units located next to each other as an integrated displacer or as an integrated power piston. 9. The heat engine according to claim 1, wherein a compressor is connected to at least one of the power piston and the displacer. 10. The heat engine according to claim 6, wherein a compressor is connected to at least one of the power piston and the displacer. 11. The heat engine according to claim 1, wherein at least one of the high-temperature space portion and the low-temperature space portion includes a bellows which is retractable both ways. 12. The heat engine according to claim 6, wherein at least one of the high-temperature space portion and the low-temperature space portion includes a bellows which is retractable both ways. 13. The heat engine according to claim 1, wherein the displacer has piston surfaces facing the high-temperature space portion and the low-temperature space portion, respectively, and moves the working gas between the high-temperature space portion and the low-temperature space portion without causing a pressure difference between the piston surfaces.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (3)
Colgate Stirling A. (Los Alamos NM), Isothermal positive displacement machinery.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.