KR200270630Y1 - rotary engine - Google Patents

Abstract

The present invention relates to a rotary engine, a cylindrical housing (A) having an inlet (9) and an exhaust port (10), a rotating body (B) rotating in the housing (A), and integrally protrudes from the housing (A) Consists of an elliptical guide (C) located in the center of the rotating body (B), one or more operating chambers (11) are formed in the rotating body (B), the piston 13 on one side of the operating chamber (11) It is installed so as to be rotatable, and the top 13c and the tail 13b of the piston 13 alternately slide in contact with the outer surface of the elliptical guide C by the rotation of the rotor B so that the top dead center and the bottom dead center. By repeatedly passing the point, the piston 13 reduces and expands the operating chamber 11, so that the four strokes of the engine are sequentially made, and the rotating shaft 1 formed integrally with the rotating body B. Lubricating oil supply passage 16 and lubricating oil discharge passage 17 are formed in the engine to smoothly lubricate the engine. In a hurry, the operation chamber 11, where fuel is combusted, is sealed with an oil seal 18 so as to prevent lubricating oil from flowing into the operation chamber 11, so as to have a lubrication function independent of the operation chamber 11. Compared with rotary engine, it has less vibration and noise, less wear of parts, simple configuration, easy to manufacture, and has independent lubrication function, so there is no risk of soot from combustion of lubricant with fuel.

Description

Rotary Institution {rotary engine}

The present invention relates to a rotary engine, the conventional rotary engine is to rotate the rotor because the four strokes of the engine is made by a triangular rotor that rotates eccentrically in a housing having an inner space of the shape of two circles combined Due to the high friction and high wear of the rotor, complicated construction and complicated construction, it is difficult to manufacture, and there is no independent lubrication function. Although it has many advantages such as small size and lightness compared to the institution, it is not realized.

In order to solve this problem, in the present invention, a cylindrical rotor rotates about a rotation axis in a cylindrical housing, and when the rotor rotates, a piston installed in the rotor rotates on an outer circumferential surface of an elliptical guide that protrudes from the center of the rotor. The four strokes of the engine are achieved by compressing and expanding the seal, so the rotational friction of the rotating body is low, so the operation is smooth and smooth.Therefore, the vibration and noise are low, the wear rate of the parts is low, and the configuration is simple. It is easy and has independent lubrication function so that there is no fear of soot by lubricating oil.

1 is a side cross-sectional view of the subject innovation.

2 is a cross-sectional configuration of the housing portion excluding the rotating body and the rotating shaft in FIG.

Fig. 3 is a cross-sectional configuration diagram of a rotating body and a rotating shaft separated from Fig. 1: Fig. 4 is a schematic diagram of a flow path for lubricating oil discharged from the bottom of the rotating body. Fig. 6 is a plan cross-sectional configuration of the present invention, in which a piston reaches a top dead center and a bottom dead center. Fig. 7 is a cross-sectional view of the piston excluding the piston in Fig. 5 9: Configuration diagram of the exhaust vent of the present invention.

<Description of the symbols for the main parts of the drawings>

(A)-housing (B)-rotating body

(C)-Guide (C-1)-Trademark

(C-2)-Lower dead center (1)-Rotating shaft

(2)-space department (3)-body

(4)-cover (5)-cooling chamber

(6)-cover (7)-fuel presser

(8)-fuel inlet pipe (9)-suction

(10)-Exhaust vent (10a)-Slope

(11)-Operating Room (12)-Intake Vent

(13)-piston (13a)-head

(13b)-tail (13c)-front

(13d))-Back (14)-Shaft (15)-Roller (16)-Lubricant supply passage (16a)-Supply hole (17)-Lubricant discharge passage (17a)-For discharge Bore (18)-Oil Seal (19)-Guide Protrusion (20)-Lubricant Drain (21)-Ignition Plug

An embodiment of the present invention is as follows.

The present invention is a cylindrical housing (A), as shown in Figure 1, a rotating body (B) which rotates integrally with the rotating shaft (1) in the cylindrical housing (A), and a rotating body (protruding from the inner wall of the housing (A) It is composed of an elliptical guide (C) located in the center of the B), the housing (A) as shown in Figure 2 and the cover (3) bolted to the main body (3) and the main body (3) formed with a space (2) ( It consists of 4), and the space part 2 is provided with the rotating body B, and rotates.

A cooling chamber 5 is formed in the main body 3 and the cover 4, respectively, to fill the cooling liquid, and the cover 6 is bolted to the bottom of the main body 3, and a turbine type installed in the cover 6 is provided. The fuel presser 7 is coupled to the rotary shaft 1 and rotates together, and a fuel inlet pipe 8 is formed at one side of the bottom of the cover 6.

The fuel intake port 9 and the gas exhaust port 10 are formed at both sides of the housing A, respectively, and the exhaust port 10 is inclined slightly in the rotation direction of the rotating body B as shown in FIG. A plurality of inclined plates (10a) were formed to increase the propulsion force during exhaust.

The rotating body B has a cylindrical body and is integrally formed with the rotating shaft 1 as shown in FIG. 3, and rotates together with the rotating shaft 1 in the housing A. As shown in FIG.

In the rotating body B, one or more operating chambers 11 are formed as shown in Fig. 5, and in each operating chamber 11, intake and exhaust holes 12 are formed in which fuel is sucked in and gas is exhausted after combustion. It is.

The intake and exhaust holes 12 perform not only the suction and exhaust functions but also the function of the operating chamber 11 as part of the operating chamber 11.

The operating chamber 11 is provided with a piston 13, the head 13a of the piston 13 is located on the opposite side of the intake and exhaust hole 12, the shaft rod 14 is installed to be rotatable on the inner wall of the rotor (B) Rotate together with the shaft 14, the tail 13b of the piston 13 is in contact with the outer surface of the elliptical guide (C) to slide.

The body of the piston 13 is curved as shown in FIG. 8, and as the rotor B rotates, the tail 13b and the front face 13c of the piston 13 are as shown in FIGS. 5 and 6. While passing through the top dead center (C-1) and the bottom dead center (C-2) of the guide (C), push the piston 13 toward the intake and exhaust holes 12 to reduce the operating chamber 11 and return to the original position. By repeating the action of expanding the operation chamber 11, the four strokes of intake, compression, expansion, and exhaust are sequentially performed.

A spring or various supporting means may be provided so that the tail 13b or the front face 13c of the piston 13 always contacts the outer surface of the guide C.

However, in the case where the rotating body B is installed to rotate horizontally, the piston 13 is pushed toward the guide table C by the injection pressure of the fuel, the expansion pressure after combustion, and the like, and thus, it is not necessary to install such support means.

Small tail rollers (not shown) may be attached to the tail portion 13b of the piston 13 to further reduce friction with the guide C during rotation.

The elliptical guide C is integrally protruded from an inner wall of one side of the housing A as shown in FIG. 2 and positioned at the center of the rotating body B, and the rotating shaft 1 penetrates through the center thereof.

The roller 15 is provided in the edge part of the long axis which is furthest from the center of the guide stand C, ie, top dead center C-1.

A lubricant supply path 16 and a lubricant discharge path 17 are formed inside the rotating shaft 1, and supply holes 16a are provided in the lubricant supply path 16 and discharge holes 17a in the lubricant discharge path 17. ) Are pierced.

An oil seal 18 is formed between the housing A and the rotor B and between the piston 13 and the rotor B, respectively, as shown in FIG. ) And the suction port 9 and the exhaust port 10 to prevent the inflow.

On the bottom of the rotating body (B) as shown in Figure 4, a plurality of guide projections 19 integrally projected radially at regular intervals so that the lubricating oil discharge promotion flow path 20 is formed to discharge the lubricating oil more quickly. It is also possible to manufacture and attach the discharge promotion plate separately formed on the bottom surface of the rotating body (B) for the discharge promotion passage 20. In the present invention, the spark plug 21 has a piston (13) guide (C). It is installed in the position where it can be ignited when passing through the top dead center (C-1) of, and in case of diesel engine, the fuel supply device is installed in the ignition position instead of the ignition plug 21. ) Rotates when the tail 13b of the piston 13, which moves in contact with the outer surface of the guide C, meets the suction opening 9 of the inlet / outlet hole 12 of the operating chamber 11; The piston 13 moves the shaft 14 to the axis because it moves to the bottom dead center (C-2) after the top dead center (C-1) of It rotates toward the center of the rotating body (B), thereby gradually expanding the operating chamber 11 that has been minimized, whereby the fuel (gas mixed with the air) injected into the fuel inlet pipe 8 enters the turbine type. It is pressurized by the fuel presser 7 and strongly suctioned through the inlet 9 to the operating chamber 11. This suctioning action is carried out while the intake and exhaust holes 12 of the operating chamber 11 pass through the inlet 9. Then, when the intake and exhaust holes 12 pass through the inlet 9, the operation chamber 11 and the intake and exhaust air are formed by the inner wall of the housing A and the oil seals 18 surrounding the operation chamber 11 and the intake and exhaust holes 12. The ball 12 is sealed and the suction stroke is completed. When the suction stroke is completed, the tail 13b of the piston 13 moves through the bottom dead center C-2 to the top dead center C-1, so the bottom dead center The operating chamber 11 (the space including the intake and exhaust holes 12), which has been made the largest volume in (C-2), gradually compresses the fuel and compresses the fuel. When 3b) reaches the top dead center (C-1), the operating chamber 11 is minimized, the fuel is compressed to the maximum, and the compression stroke is completed. At this time, when the ignition plug 21 is ignited, the fuel is burned. The expansion stroke starts, and the expansion force pushes the back surface 13d of the piston 13, so that the rotational force for rotating the rotating body B counterclockwise is generated. In this case, the tail portion 13b of the piston 13 The operating chamber 11 gradually expands as it moves to the bottom dead center C-2 after passing through the top dead center C-1, and the rotation is continued so that the intake and exhaust holes 12 of the operating chamber 11 are connected to the exhaust port 10. When it meets, the expansion stroke is completed and the exhaust stroke is started. When the exhaust stroke is started, the tail 13b of the piston 13 passes through the bottom dead center C-2 to the top dead center C-1, As a result, the operation chamber 11 that has been maximized in size gradually decreases, and exhaust proceeds rapidly. When the intake and exhaust holes 12 of the operation chamber 11 completely pass through the exhaust port 10, When the exhaust stroke is completed, the tail 13b of the piston 13 passes again through the top dead center C-1 to the bottom dead center C-2, and the operating chamber 11 that has been minimized is returned. It gradually expands and repeats the first suction stroke to suck the fuel through the inlet 9. The lubricant supplied through the lubricant supply path 16 of the rotating shaft 1 during the stroke is supplied for supply. Through the hole 16a, it flows evenly between the housing A and the rotating body B, between the rotating body B and the piston 13, between the rotating shaft 1, the housing A, and the guide C. Smooth rotation and discharge through the lubricating oil discharge hole (17a) and the lubricating oil discharge path (17), the lubricating oil is not introduced into the inlet (9) and the exhaust port (10), the operating chamber (11) and the intake and exhaust holes (12). Since the oil seal 18 is sealed to prevent the lubricating oil from being burned together with the fuel so as not to generate soot. 9 is provided with a plurality of inclined plates 10a as shown in FIG. 9, so that more propulsion power can be obtained by the action of the inclined plate 10a when exhausting. When the rotating body B rotates, the radial guide protrusions 19 The lubricating oil moves quickly to the center, and the discharge is more smooth.

The present invention, the piston 13 of the rotating body (B) is in contact with the outer surface of the guide (C) while the four strokes of the engine is made while the triangular rotor rotates eccentrically, the conventional rotary engine made of four strokes of the engine Compared with the lower friction, the operation is smooth and smooth. Therefore, the noise and vibration are low, the piston 13 has low wear rate, and the configuration is relatively simple, so it is easy to manufacture and has the independent lubrication function. It is effective that there is no fear of occurrence.

Claims (6)

Cylindrical housing A, a rotating body B that rotates in the housing A, an elliptical guide C that protrudes from the housing A and is located in the center of the rotating body B, and the housing A. ) And guide shaft (C) and a rotating shaft (1) formed integrally with the rotating body (B), the inlet (9) and the exhaust port (10) and the spark plug 21 is formed in the housing (A) At least one operating chamber 11 having the intake and exhaust holes 12 is formed in the rotating body B, and the piston 13 is rotatably installed at one side of the operating chamber 11 so that the tail portion 13b and the front surface thereof can be rotated. Rotary institution, in which (13c) is brought into contact with the outer circumferential surface of guide (C) in turn and slides. The lubricating oil supply path 16, the supply hole 16a, the lubricating oil discharge path 17, and the discharge hole 17a are formed in the rotating shaft 1, and the operation chamber 11 and Rotary engine is sealed by the oil seal (18) around the intake and exhaust holes (12). Rotary engine according to claim 1, characterized in that the body of the piston (13) is curved. The rotary engine according to claim 1, wherein a fuel presser (7) is provided on one side of the housing (A). The rotary engine according to claim 1, wherein a plurality of inclined plates (10a) are provided in the exhaust port (10). The rotary engine according to claim 1, wherein a plurality of guide protrusions (19) are radially formed on the bottom surface of the rotating plate (B).