KR102115944B1 - Stirling engine cylinder - Google Patents

Abstract

Disclosed herein is a structure of a flow path connected to a Stirling engine cylinder. According to an embodiment of the present invention, the fluid flowing into the cylinder through the surface flow path contacts the cylinder wall and flows into the cylinder to improve heat transfer efficiency.
In addition, by connecting the flow path in the circumferential direction of the cylinder, the fluid flowing into the cylinder may form a vortex, thereby further improving the heat transfer efficiency with the cylinder wall.

Description

STIRLING ENGINE CYLINDER}

The present invention relates to a Stirling engine cylinder, and more particularly, to an arrangement structure of a flow path connected to the Stirling engine cylinder.

The Stirling Engine is a device that converts heat energy into kinetic energy by compressing and expanding fluid in a closed space at different temperatures.

The Stirling engine has the highest thermal efficiency in theory of thermodynamics, and because there is no explosive stroke when combusting, the engine's vibration and noise are low. In addition, because it is an external combustion engine, it is a heat engine that can use not only fossil fuels, but also oil, natural gas, wood-based fuels, factory waste heat, and solar heat.

The principle of the Stirling Institute is known to have been devised by the British pastor Stirling in 1816. However, the rapid development of steam engines and internal combustion engines failed to receive light, and in recent years, the development of related technologies, especially heat-resistant materials and seal technology, and the importance of energy saving and alternative energy, began to be redeveloped.

First, the principle of operation of the Stirling engine will be described. The Alpha Stirling engine basically consists of two cylinders and two pistons. One cylinder is a low-temperature cylinder that emits low-temperature working gas and discharges heat to the outside, and the other is a high-temperature cylinder that receives high-temperature working gas and receives heat energy from a heat source.

The two pistons respectively provided in the low-temperature section and the high-temperature section cylinder are connected to one crankshaft to form a constant phase difference, thereby operating in a certain order by compression and expansion of the working gas. The operation of the piston, that is, the reciprocating motion of the piston due to the compression and expansion of the working gas, is converted into a rotational motion of the crankshaft.

Of the two pistons, the piston provided in the low-temperature cylinder serves as a displacer piston that moves the working gas from the low-temperature cylinder to the high-temperature cylinder, and the piston provided in the high-temperature cylinder converts compression and expansion of the working gas by thermal energy into kinetic energy. Acts as a power piston.

The Alpha Stirling engine is the most basic form of Stirling engine. In addition, there is a Beta Stirling engine in which one cylinder has both a power piston and a displacer piston. Other types of Stirling engines operate on the same principle as the Alpha Stirling engines and have a similar structure.

According to the conventional method in which the flow path is connected to the Stirling engine cylinder, the fluid flows directly into the center of the cylinder through the flow path. This is illustrated in FIG. 1. In such a case, there is a problem in that heat transfer is not efficient in heating and cooling because the cylinder wall heated by the heat source does not directly contact the fluid flowing into the center of the cylinder. Specifically, since the fluid is heated by the heated cylinder wall, and the heated fluid is transferred to the internal fluid again, there is a problem that efficiency is not high in terms of heat transfer efficiency.

Embodiments of the present invention are to improve the thermal efficiency, which was not good due to the connection structure between the conventional Stirling engine cylinder and the flow path.

According to an aspect of the present invention, a cylinder in a Stirling engine cylinder; A piston; A connecting rod; A crankshaft; The singular or plural flow passages are connected to the cylinder wall in a tangential direction to the cylinder circumference when the Stirling engine is operated so that a vortex may be formed through the cylinder wall when fluid flows into the cylinder.

In addition, the singular or plural flow paths may have a straight shape.

In addition, at least one or more of the singular or plural flow paths may include a curved shape.

Furthermore, adjacent distances between the cylinder circumference and the plurality of points formed by the plurality of flow paths may be the same.

According to an aspect of the present invention, a cylinder in a Stirling engine cylinder; A piston; A connecting rod; A crankshaft; Including singular or plural flow paths,

The singular or plural flow paths are not tangential to the cylinder circumference when the Stirling engine is operated, but are connected to the cylinder wall so as to be located on the tangential surface of the cylinder circumference, and thus flow along the cylinder wall when fluid flows into the cylinder. Can be.

In addition, the singular or plural flow paths may have a straight shape.

In addition, at least one or more of the singular or plural flow paths may include a curved shape.

Furthermore, adjacent distances between the cylinder circumference and the plurality of points formed by the plurality of flow paths may be the same.

In embodiments of the present invention, the flow path connected to the cylinder is located on the tangential surface, so that the fluid flowing into the cylinder flows directly over the cylinder wall, thereby increasing heat transfer efficiency.

In addition, it is possible to improve the power of the engine by increasing the heat transfer efficiency in the fluid in the cylinder.

In addition, in the conventional flow path connection method, there is a limitation in terms of heat transfer efficiency, so the size of the engine is limited, but according to the present invention, the heat transfer efficiency is improved, so that the engine output can be further improved by increasing the size of the engine.

1 is a basic conceptual diagram of a conventional connection method between a Stirling engine cylinder and a flow path.
2 is a basic conceptual diagram of a connection method between a Stirling engine cylinder and a flow path according to an embodiment of the present invention.
3 is an embodiment of the present invention, a perspective view of a Stirling engine cylinder with a flow path connected to the cylinder circumferential tangential direction.
4 is a perspective view of the Stirling engine cylinder in which the flow path of FIG. 3 is connected to a tangential surface, not a cylinder circumferential tangential direction.
5 is a basic conceptual diagram of increasing the number of flow paths in FIG. 2.
6 is an embodiment of the present invention, and is a basic conceptual diagram of an alpha Stirling engine to which the present invention is applied.
7 is an embodiment of the present invention, a cross-sectional view of a cylinder applying a straight flow path to an alpha Stirling engine in which two pistons in one cylinder are oriented 180 degrees.
8 is a view having the entire flow path of FIG. 7 bent.
9 is a view having a curved portion of the flow path of FIG. 7.

Conventionally, a flow path is connected to the Stirling engine cylinder so that the flow path faces the center of the cylinder. On the other hand, it is shown simply in FIG. 1. By passing the flow path toward the center of the cylinder, the incoming air did not receive heat transfer directly from the heated cylinder wall. Since the fluid is heated by the heated cylinder wall, and the heated fluid is transferred to the internal fluid again, there is a problem that the efficiency is not high in terms of heat transfer efficiency. Therefore, in order to solve the above problems, the present invention is to improve the heat transfer efficiency of the fluid in the cylinder by changing the connection structure of the flow path.

Hereinafter, basic terms for describing an embodiment of the present invention will be briefly described. The cylinder circumferences 10 and 110 indicate the circumferential length of the uppermost side of the cylinder 100 in a cylindrical shape. The flow paths 20, 120a, 120b, 120c, 120d, 120e, 120f, 120g, and 120h are passages for fluid movement by connecting between the high-temperature cylinder and the low-temperature cylinder, and the cylinder 100 uses the cylinder wall 112 as the body part. By including the piston 130 therein. The cylinder wall 112 receives heat energy from an external heat source and serves to transfer heat energy to the fluid inside the cylinder 100. The connecting rod 140 connected from the piston 130 to the crankshaft 150 transmits kinetic energy of the piston 130 to the crankshaft 150. The linear movement of the piston 130 may be converted to the rotational movement of the crankshaft 150 by the connecting rod 140.

Hereinafter, the claims of the present application will be described in detail. According to an embodiment of the present invention, the singular or plural flow paths are tangentially connected to the cylinder circumference 110. It means that the angle between the center line crossing the center of the flow path section and the tangent line of the cylinder circumference 110 is approximately 90 degrees parallel to the flow paths 120a, 120b, 120c, 120d, 120e, 120f, and 120g. Furthermore, although an angle smaller or larger than about 90 degrees can be easily considered, it is ideal that the angle between the center line and the tangent line is about 90 degrees for the purpose of improving the heat transfer efficiency, which is the object of the present invention. However, it means that the angle between the center line and the tangent line is approximately 90 degrees, and an embodiment of the present invention includes other angles.

The fluid introduced into the cylinder through the singular or plural flow paths 120a, 120b, 120c, 120d, 120e, 120f, and 120g tangentially connected to the cylinder circumference 110 is a cylinder circumference near the flow path 110a, 110b ), The path of the fluid is corrected by collision with the cylinder wall 112 connected, and then the fluid forms a vortex through continuous collision. In some cases, the number of flow paths (120a, 120b, 120c, 120d, 120e, 120f, 120g) connected to the cylinder will be different, but the fluids introduced through the flow paths are mixed with each other during the flow of forming a vortex to create a larger vortex. To form.

Since the vortex is an air stream flowing in contact with the cylinder wall 112, heat energy from the cylinder wall 112 can be directly transferred, so that the heat transfer rate can be improved compared to the fluid flowing into the central portion of the conventional cylinder. In addition, in the conventional method, the fluid is introduced by linearly moving into the cylinder 100, but in the case of the present invention, it is rotated. Therefore, the transfer speed of the fluid is faster than in the prior art, and heat transfer from the cylinder wall 112 is made smoother.

Figures 2 to 4 show the shape of the vortex. In addition, although not explicitly shown in the drawings, in the embodiment shown in FIGS. 5 to 8, the vortex is formed when the Stirling engine is operated.

In embodiments of the present invention, unlike the tangential connection of the aforementioned flow paths 120a, 120b, 120c, 120d, 120e, 120f, 120g, the flow path 120h can be connected to the tangential surface of the cylinder circumference. More specifically, the flow path connected to the cylinder is connected to the cylinder wall 112 so that it is located on the tangential surface of the cylinder circumference 110 rather than the tangential direction of the cylinder circumference 110.

Figure 3 is a flow path (120a, 120b) is connected to the cylinder wall 112 in the tangential direction of the cylinder circumference 110, Figure 4 is a flow path (120a, 120b) is a cylinder in a direction having a certain angle with the cylinder circumferential surface It is connected to the wall 112. As described above, the structure in which the flow path 120h is connected so that the fluid flowing in while not being flush with the cylinder circumferential surface is in contact with the cylinder wall 112 and flows into the cylinder 100 is tangential to the cylinder circumference 110. Rather, it is described as being positioned on the tangent surface of the cylinder circumference 110. In the case of the above-described flow path connection method, vortex formation may be more difficult than the tangential connection of the above-described flow paths 120a, 120b, 120c, 120d, 120e, 120f, and 120g. Therefore, ideally, the flow paths 120a, 120b, 120c, 120d, 120e, 120f, and 120g are connected in the tangential direction of the cylinder circumference 110, and it is advantageous in terms of improving heat transfer efficiency through the tangential connection.

Also, in the case of FIG. 9, the flow path 120h is not the tangential direction of the cylinder circumference 110, but is located on the tangential surface of the cylinder circumference 110. In this case, the flow path is connected to the cylinder 100 so as to be perpendicular to the cylinder circumferential surface. Although a smooth vortex may not be formed inside the cylinder 100, the heat energy can be directly transferred by flowing by contacting the cylinder wall 112, thereby meeting the purpose of improving the thermal efficiency of the present invention.

The flow paths 120a, 120b, 120c, 120d, 120e, 120f, 120g used in the embodiment of the present invention have a straight shape, and the shapes of the flow paths therefor may be as illustrated in FIGS. 2 to 7.

In addition, the flow paths 120h used in the embodiment of the present invention may include at least one or more flow paths, and the shapes of the flow paths 120h for this may be as shown in FIGS. 8 to 9. Can be. 8, the entire flow path 120h has a curved shape, and in FIG. 9, the flow path 120h includes a curved shape. The curved shape may vary, and is not limited to the shape of the flow paths 120h shown in the drawings herein. In addition, since the flow efficiency of the Stirling engine may be lowered due to the movement of the fluid 120h being restricted due to the bending of the flow path 120h, it is preferable that the flow path 120h preferably includes at least the curved shape of the flow path 120h. .

In an embodiment of the present invention, the adjacent distance between the cylinder circumference 110 and the plurality of points formed by the plurality of flow paths 120a, 120b, 120c, 120d, 120e, 120f, 120g, 120h may be the same, This is illustrated in FIGS. 2 to 5. By making the adjacent distances the same, the fluid inside the cylinder 100 can be uniformly discharged and introduced. By uniformly flowing and flowing fluid in the cylinder 100 smoothly, energy efficiency of the engine can be improved.

Hereinafter, examples of the present invention will be described.

6 shows an embodiment in which the present invention is applied to a basic alpha Stirling engine of a Stirling engine. 6 is a basic conceptual diagram, which is not specifically shown for the Alpha Stirling engine, but simply and clearly shows the principle in which the present invention is applied and works. In addition, the two pistons 130 should be connected to one crankshaft 150 so as to form a constant phase difference, but this is not strictly illustrated in the drawings, regardless of the features of the present invention.

One flow path (120g) is connected to each of the high-temperature cylinder and the low-temperature cylinder, and the connection method is connected to the cylinder wall 112 in a tangential direction to the cylinder circumference 110 of each cylinder 100. Although the flow of the fluid is not shown, the fluid flowing in and out through the flow path 120g by the operation of the Alpha Stirling engine forms a vortex inside the cylinder 100. In addition, in order to minimize the passage path, the passages 120g connected between both cylinders 100 may have a straight line shape.

Although not illustrated in FIG. 6, in some cases, a plurality of flow paths 120g connected to the cylinder 100 of the alpha Stirling engine may be provided.

In addition, although not shown in the drawings of the present application, the principle of the present invention can be applied to a beta Stirling engine. By forming a long groove in the form of a screw on the outer wall of the displacer, a flow of fluid moving through the movement of the displacer can be formed into a vortex contacting the cylinder wall. With the above principle, the present invention is not applicable only to the Alpha Stirling engine.

7 to 9 are views showing an embodiment of the present invention applied to an alpha stirling engine in which two pistons 130 are disposed at 180 degrees in one cylinder 100, not a general alpha stirling engine. 7 to 9 are examples in which only the shape of the flow path 120h is different.

In the drawings, (a) represents a case where fluid is present in the lower region of the cylinder 100, and (b) represents a case where fluid is present in the upper region of the cylinder 100. In addition, for simplicity and clarity, although not shown in the drawings, the upper region of the cylinder 100 means a high temperature portion.

With the operation of the Stirling engine, by applying thermal energy to the upper region of the cylinder 100, the upper region contains a high-temperature fluid. As the fluid expands due to thermal energy, the piston 130 located in the upper region of the cylinder 100 descends, and the piston 130 located in the lower region of the cylinder 100 also descends. As the piston 130 of the lower region descends, fluids located in the lower region of the cylinder 100 move to the upper region of the cylinder 100 through the flow path 120h.

7 or 8, the flow path 120h is connected in a tangential direction of the cylinder circumference 110, so that the fluid flowing into the cylinder 100 forms a vortex. However, in the case of FIG. 9, the flow path 120h is connected to the cylinder 100 so as to be located on the tangential surface of the cylinder circumference 110 rather than the tangential direction of the cylinder circumference 110, so the fluid introduced into the cylinder 100 is It does not form a vortex.

As another embodiment of the present invention, the plurality of flow paths (120a, 120b, 120c, 120d, 120e, 120f, 120g, 120h) in the cylinder 100 is arranged in the circumferential direction on the cylinder circumference or cylinder wall Assuming cross sections including the center line of, the cross sections for the plurality of flow paths 120a, 120b, 120c, 120d, 120e, 120f, 120g, 120h may be designed so as not to be arranged on the same plane. Specifically, when a plurality of flow paths (120a, 120b, 120c, 120d, 120e, 120f, 120g, 120h) are arranged on the cylinder wall 112 as described above, the flow into the cylinder () 100 through each flow path The fluids are initially concentrated as one fluid inside the cylinder 100 so as not to form a fluid mass. On the other hand, when the cross sections for the plurality of flow paths 120a, 120b, 120c, 120d, 120e, 120f, 120g, and 120h are designed to be disposed on the same plane, the fluids introduced into the cylinder 100 are cylinders ( 100) The heat transfer is achieved while forming a vortex through the inner wall of the cylinder 100 in the state of a bulky fluid mass that is initially concentrated as one fluid from the inside.

When the cross sections for the plurality of flow paths 120a, 120b, 120c, 120d, 120e, 120f, 120g, and 120h are designed not to be disposed on the same plane, fluids introduced into the cylinder 100 are one It is possible to perform more efficient heat transfer by increasing the surface area of the fluid inside the cylinder 100 by forming a vortex while riding on the inner wall surface of the cylinder 100 with several forked fluid stems without being formed as a fluid mass.

As described above, one embodiment of the present invention has been described, but those skilled in the art can add, change, delete, or add elements within the scope of the present invention as described in the claims. It will be said that the present invention can be variously modified and changed by the like, and this is also included within the scope of the present invention.

10, 110: Cylinder circumference
20, 120a, 120b, 120c, 120d, 120e, 120f, 120g, 120h: Euro
100: cylinder
110a, 110b: Cylinder circumference near the flow path
112: cylinder wall
130: piston
140: connecting rod
150: crankshaft

Claims (7)

In the Stirling engine cylinder,
A cylinder;
A plurality of pistons disposed in the cylinder at 180 degrees;
A crankshaft;
A plurality of connecting rods connecting the respective pistons and the crankshaft;
It includes a singular or a plurality of flow paths connecting the upper and lower regions between the respective pistons and the cylinder facing the same,
The singular or plural flow paths are connected to the cylinder wall in a tangential direction to the cylinder circumference when the Stirling engine is operated, so that a vortex is formed through the cylinder wall when fluid flows into the cylinder. According to claim 1,
Stirling engine cylinder, characterized in that the singular or plural flow paths have a straight shape. According to claim 1,
A Stirling engine cylinder comprising at least one or more of the singular or plural flow paths having a curved shape. In the Stirling engine cylinder,
A cylinder;
A plurality of pistons disposed in the cylinder at 180 degrees;
A crankshaft;
A plurality of connecting rods connecting the respective pistons and the crankshaft;
It includes a singular or a plurality of flow paths connecting the upper and lower regions between the respective pistons and the cylinder facing the same,
The single or plural flow paths are not tangential to the cylinder circumference when the Stirling engine is operated, but are connected to the cylinder wall so as to be located on the tangential surface of the cylinder circumference, and thus flow along the cylinder wall when fluid flows into the cylinder. Engine cylinder. According to claim 4,
Stirling engine cylinder, characterized in that the singular or plural flow paths have a straight shape. According to claim 4,
A Stirling engine cylinder comprising at least one or more of the singular or plural flow paths having a curved shape. The method according to any one of claims 1 to 6,
Stirling engine cylinder, characterized in that the cylinder circumference and the adjacent distance between the plurality of points formed by the plurality of flow paths are the same.

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