CLOSED CYCLE ENGINE POWER STRUCTURE AND POWER GENERATION METHOD

Abstract

A closed cycle engine power structure and a power generation method, includes a cylinder block and an inner shell. The inner shell is located at the cylinder block, and the inner enclosed cavity of the cylinder block is divided into an outer duct and an inner duct, and an electric coil is arranged in the inner shell. An Archimedes pump is arranged in the inner duct, the electric coil is in drive connection with the Archimedes pump to form a motor structure. Tension structures are arranged in the outer duct. The Archimedes pump is driven to rotate to form a pressure difference between the top and bottom of the cylinder block, generating airflow around the tension structures. According to Bernoulli principle, the pulling force is generated by tension structures. The tension structures concentrate on the cylinder block to form the power of the engine power structure.

Claims

1. A closed cycle engine power structure, comprising a cylinder block (1) and an inner shell (2); the inner shell (2) is located at the center of the cylinder block (1), and the inner enclosed cavity of the cylinder block (1) is divided into an outer duct (3) and an inner duct (4), an electric coil (21) is arranged in the inner shell (2), and an Archimedes pump is arranged in the inner duct (4); the electric coil (21) and the Archimedes pump (41) are in drive connection to form a motor structure, and a plurality of tension structures (31) are arranged on the outer duct (3).

2. The closed cycle engine power structure according to claim 1, wherein the tension structure (31) comprises a horizontal baffle (311) and a tension chamber (312), two sides of the horizontal baffle (311) are respectively connected to an inner wall of the cylinder block (1) and an outer wall of the inner shell (2), and the tension chamber (312) is uniformly fixed on the horizontal baffle (311).

3. The closed cycle engine power structure according to claim 2, wherein an interior of the tension chamber (312) is an enclosed cavity.

4. The closed cycle engine power structure according to claim 2, wherein the plurality of tension structures (31) are distributed in equidistance along an axis of the outer duct (3).

5. The closed cycle engine power structure according to claim 1, wherein the inner shell (2) comprises a plurality of support members (23); a hollow chamber configured for accommodating the electric coil (21) is provided in a casing (22); the Archimedes pump (41) is provided in the inner duct (4) which is inside the casing (22); each of the plurality of support members (23) is connected to the casing (22) and the cylinder block (1).

6. The closed cycle engine power structure according to claim 5, wherein the Archimedes pump (41) comprises an iron core (411) and a plurality of helical surfaces (412); each of the plurality of helical surfaces (412) is fixedly socketed on the iron core (411) at equal intervals, so as to divide the inner duct (4) into a plurality of rotating acceleration chambers.

7. The closed cycle engine power structure according to claim 6, wherein the cylinder block (1) comprises the upper cylinder block (11) and the lower cylinder block (12), and the upper cylinder block (l) and the lower cylinder block (12) are butted to form a structure. of the cylinder block (1).

8. The closed cycle engine power structure according to claim 7, wherein the cylinder block (1) and the support members (23) are provided with a line channel (13) and the electric coil (21) is connected to external power supply equipment through the line channel (13).

9. A power generation method of a closed cycle engine, adopting any one of power structure of the closed cycle engine according to claim 1, and the method comprises the following steps: S1. butting an upper cylinder block (11) with a lower cylinder block (12) to form the cylinder block (1), wherein an enclosed inner cavity is formed in an interior of the power structure of the engine; S2. providing a motor structure to connected with an external power supply to drive an Archimedes pump (41) to rotate; S3. pumping air in the inner duct (4) from the bottom of the inner duct (4) to the top of the inner duct (4) by the Archimedes pump (41) to form a high pressure area in the top of the inner duct (4) and a low pressure area in the bottom of the inner duct (4), thereby an airflow generates via the outer duct (3) from the top of inner duct (4) to the bottom of inner duct (4); S4. the pressure on the top of tension chamber (312) is reduced when the airflow is blown frontally to the tension chamber (312) increasing the velocity of airflow. Forming a pressure difference compared to the air in the internal cavity of the tension chamber (312). generating a pulling force opposite to the direction of the airflow in the tension chamber (312); S5. Concentrating, pulling forces generated in a plurality of tension structures to form a total power on the cylinder block (1), so as to generate a power along an axis of the cylinder block (1) in the power structure of the engine.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] FIG. 1 is a structural view showing the power structure of an embodiment of the present invention.

[0019] FIG. 2 is a top view showing the power structure of an embodiment of the present invention.

[0020] In the drawings 1. cylinder block, 2. inner shell, 3. outer duct, 4. inner duct, 11. upper cylinder block, 12. lower cylinder block, 13. line channel, 21. electric coil, 22. casing, 23. support member, 31. tension structure, 41. Archimedes pump, 311. horizontal baffle, 312. tension chamber, 411. iron core, 412. helical surface.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0021] In order to facilitate the understanding of those skilled person in the art, the technical solutions of the present invention are further described below in conjunction with the accompanying drawings and embodiments.

Embodiment 1

[0022] As shown in FIG. 1, a closed cycle engine power stricture includes an inner shell (2) and a cylinder block (1). The inner shell (2) is disposed in the middle of the cylinder block (1), and divides the enclosed internal cavity of the cylinder block (1) into an inner duct (4) and an outer duct (3). The inner shell (2) includes an electric coil (21), a casing (22) and a support member (23). A hollow chamber is placed in the casing (22), and the electric coil (21) is disposed in the hollow chamber. There are provided with several the support members (23) connected the casing (22) and the cylinder block (1), so that the casing (22) is supported inside the cylinder block (1).

[0023] The inner duct (4) inside the casing (22) is disposed with an Archimedes pump (41). The Archimedes pump (41) includes an iron core (411) and a plurality of helical surfaces (412). The helical surfaces (412) is fixedly socketed on the iron core at equal intervals, so that the inner duct (4) are divided into a plurality of rotating acceleration chambers. At the same time, the iron core (411) and the electric coil (21) formed a motor structure, and the electrified electric coil (21) drives the iron core (411) to rotate, thereby driving the whole Archimedes pump (41) to rotate.

[0024] As shown in FIG. 1 and FIG. 2, the outer duct (3) is disposed with a plurality of tensile structures (31), and the tensile structures (31) are evenly distributed in the outer duct (3) along in the axial direction and the radial direction of the outer duct (3). The tension structure (31) includes a horizontal baffle (311) and a tension chamber (312). The two sides of the horizontal baffles (311) are fixedly connected to the inner wall of the cylinder block (1) and the outer wall of the inner shell (2), respectively, there are air path configured for the airflow flowing between the adjacent tension structure (31), especially the horizontal baffle (311). The tension chamber (312) is hemispherical, and of course, it may be ellipsoid or other shape that satisfies the decompression condition of the Bernoulli principle. In the present embodiment, the tension chamber (312) is hemispherical, that is, the upper part is a sphere and the lower part is a plane. The tension chamber (312) is fixedly disposed on the horizontal baffle (311) and the tension chamber (312) form an enclosed cavity inside. In the axial direction of the outer duct (3), the adjacent tension structures (31) are staggered from each other to ensure that each of the tension chambers (312) has airflow around.

Embodiment 2

[0025] The present embodiment is similar to the embodiment 1. Further, as shown in FIG. 1, the cylinder block (1) is formed by butting of the upper cylinder block 11 and the lower cylinder block (12), and can be separated into the upper cylinder block (11) and the lower cylinder block (12) during installation and maintenance, so that the closing and opening of the cylinder block (1) is achieved. The cylinder block (1) and the support member (23) are further configured with a line channel (13) through which the electric coil (21) can be connected to an external power source.

[0026] In operation, the electric coil (21) is electrified to drive the iron core (411) to rotated, thereby driving the entire Archimedes pump (41) to rotate, and the air at the bottom of the cylinder block (1) is pumped from one rotating acceleration chamber into another rotating acceleration chamber in the top direction in the way of spiral. The air density in the bottom of cylinder block (1) decreases and the air in the top of the cylinder block (1) increases, a lower pressure area is formed at the bottom and a higher pressure area is formed at the top. Due to the difference in air pressure, it generates airflow via the outer duct (3), which from the top of the cylinder block to the bottom. The airflow flows around the tension chamber (312) and the airflow velocity is increased, so that the air pressure is reduced, and the pressure difference compared to the air in the enclosed cavity inside the tension chamber (312) so as to form a pulling force opposite to the airflow direction. Concentrating The pulling force formed by each tension chamber (312) on the cylinder block (1) to form a forward power of the engine.

Embodiment 3

[0027] As shown in FIGS. 1 and 2, a power generation method of a closed cycle engine, which adopts the power structure of the closed cycle engine as mentioned above. The method includes the steps as following: S1. An upper cylinder block (11) is butted with a lower cylinder block (12) to form the cylinder block (1), wherein an enclosed inner cavity is formed in the interior of the power structure of the engine; S2. A motor structure is connected with an external power supply source to drive an Archimedes pump (41) to rotate; S3. The air in the inner duct (4) is pumped from the bottom of the inner duct (4) to the top of the inner duct (4) by the Archimedes pump (41) to form a higher pressure area in the top of the inner duct (4) and a lower pressure area in the bottom of the inner duct (4), wherein an airflow flows via the outer duct (3) from the top of inner duct (4) to the bottom of inner duct (4); S4. the pressure on the top of tension chamber (312) is reduced when the airflow is blown frontally to the tension chamber (312) increasing the velocity of airflow. Forming a pressure difference compared to the air in the internal cavity of the tension chamber (312) generating a pulling force opposite to a direction of the airflow in the tension chamber (312); S5. Concentrate pulling forces generated in a plurality of tension structures to form a total power on the cylinder block (1), so as to generate the power along the axis of the cylinder block (1) in the power structure of the engine.

[0028] Obviously, the above-described embodiments of the present invention are only examples for clearly illustrating the present invention, which are not limitations to the embodiments of the present invention. For the ordinary skilled person in the art, various modifications or changes can be made on the basis of the above description There is no need and no way to exhaust all the implementation methods here. Any modification, equivalent replacement and improvement made within the spirit and principles of the present invention shall be included in the scope of the claims of the present invention.