JPS59113289A - Rotary compressor - Google Patents

Abstract

PURPOSE:To eliminate meshing parts and eliminate noise by effecting the effect of a compressor in one set of casing by one cylindrical body, one vane and one rotor. CONSTITUTION:When a driving body 8 is rotated clockwise, the cylindrical body 4 in the casing 1 is rotated by the vane 7 fixed to the rotor 6, fluid is sucked after the vane 7 and is compressed in front of the vane, thereafter, is discharged by opening a valve when the vane 7 has come before a discharging port 3. Accordingly, two sets of rotors arranged eccentrically will never be meshed to rotate and, therefore, leakage of pressure and noise may be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a rotary compressor equipped with a supercharging mechanism.

Conventional rotary compressors have two rotors that mesh together and rotate within a casing.As the gears that move are worn out, the rotors mesh poorly, making loud noises and reducing compression efficiency. In addition, in the case where the rotor rotates eccentrically within the casing, the rotor is rotatably fitted around the outer periphery of an eccentric shaft and is made to move up and down at one point.
When the eccentric shaft is turned, the rotor does not rotate but is simply shaken inside the casing, which is unreasonable, and a seal that prevents compression leaks cannot be used, resulting in poor efficiency.This invention eliminates these drawbacks and further improves efficiency. This is what I did.

Embodiments of this invention will be explained with reference to the drawings.

Figure 1 shows embodiment (1) of the present invention, in which a part of the outer circumference of a perfectly circular cylindrical body (4) is rotatably in contact with the perfectly circular casing (1) and is rotatable at an eccentric position. A rotor (6) fixed concentrically to the drive shaft (8) is arranged in the center of the casing (1) within the cylindrical body (4), and a blade (7) is fixed on the outer periphery of the cylindrical body ( 4) Hole (5)
The hole (5) is made so that it can rotate while contacting the inner circumference of the casing (1), and the hole (5) allows the blade (7) to slide as shown in Figure 3 so that the compressed air does not deviate. Inside the casing (1), semicircular plane parts are in contact with both sides of the casing (7), and the semicircular sides fit into the semicircular recesses formed on both sides of the hole (5) of the cylindrical body (4). An inlet (3) is provided on one side of the cylindrical body (4), and an outlet (2) is provided on the other side, and a valve mechanism (not shown) is provided for the compression process. To explain the operation of this embodiment (1), when the drive shaft (8) is turned clockwise toward the drawing, the blades (7) fixed to the rotor (6) turn the cylindrical body (4). After (7), it is sucked in, compressed at the front, and when the vane (7) comes in front of the discharge port (3), the valve opens and the fluid is discharged.

This invention differs from conventional rotary compressors in that the two deformed rotors mesh and do not rotate, so there is no pressure leakage or noise, and unlike in eccentric types, the rotor does not rotate and does not swing up and down. The parts rotate completely, so there is no effort and it is efficient.

Figure 2 shows embodiment (2) of the present invention, in which the rotor (6) is enlarged and a contact point B is provided on the inner circumference of the cylindrical body (4), and the blades (7) move. There is an inlet of a communication port (9) for discharging in front of contact B on the incoming side, and an outlet is open in the casing (1), and an inlet port (10) is provided on the opposite side of contact B. . Now the rotor (6)
When you turn clockwise, the blade (7) will open inside the casing (1).
It rotates while compressing the air that has already been taken in at the front of the casing (4), while it rotates while compressing the air with a shift of half a turn in the cylindrical body (4), so that the air supply ends when it is half compressed in the casing (1). . At this time, the introduced air is not compressed, so the pressure due to this action is not applied to the vanes (7), so efficiency does not decrease, and the effect is very large because it is supercharged into the casing (1).

Although two embodiments of the present invention have been shown above, the present invention is not limited to these embodiments. For example, compression leakage can be reduced by widening the contact point A instead of having one point per point, and the valve mechanism can also be made like a mushroom. Instead of using complex known devices such as rotor type, rotor type, sliding type, etc., the contact point A is widened, a discharge port is provided in the contact point A, and a recess is formed on the surface of the cylindrical body (4) on the front side of the blade (7). By forming the seal (11), the blade (7) can be easily discharged when the discharge port and the recess match.
) The side in contact with the cylindrical body (4) may be semicircular and the recess of the hole (5) may be square.The hole (5) may also be made by splitting the cylindrical body (4) at one place. It may be shaped like a box with a bottom and a cut is made from one side.

Although the present invention is configured as described above, the present invention has the following excellent effects. Inside one casing, one cylindrical body, one blade, and one rotor perform the rotary compressor and the process of supercharging it at the same time, and because of this, the number of parts is small, and the rotating parts are Rotary motors perform complete rotational motion without eccentric rotation, have few moving parts, so there is no compression, no meshing parts, so no noise, and no pressure is applied to the supercharging blades, so there is no power loss. As a compressor, it has excellent compression efficiency.

[Brief explanation of drawings]

FIG. 1 is a sectional view of embodiment (1) of the present invention. FIG. 2 is a sectional view of embodiment (2) of the present invention. FIG. 3 is an enlarged sectional view of the seal (11) of embodiments (1) and (2) of the present invention. 1...Casing. 2...Intake port. 3...Exhaust port. 4... Cylindrical body. 5...hole. 6...Rotor. 7... Feather. 8...Drive shaft. 9...
Contact point. 10...Inhalation port. 11, 11... Seal. A, B...
contact. Patent applicant Sane Tamasaki

Claims (1)

[Claims] Contact A with an appropriate gap inside the perfectly circular casing (1)
A perfectly circular cylindrical body (4) is rotatably arranged at an eccentric position with Casing (1)
A rotor (6) with movable blades (7) fixed thereon is arranged, an inlet (2) is provided on one side of the contact A, an outlet (3) is provided on the other side, and a valve is provided at the outlet (3). A rotary compressor is constructed by providing a mechanism, and a rotary compressor is constructed by providing a contact point B with an appropriate gap between the casing (1) and the rotary (6) in the cylindrical body (4). By providing an internal communication port (9) and rotating the rotor (6), suction, compression, and discharge strokes are performed within the casing (1), and during the suction stroke, the cylindrical body (
4) A rotary compressor that can be supercharged from inside through the connection port (9).