KR100323064B1 - Compact compressor - Google Patents

Abstract

The present invention relates to a compact compressor, to be supplied from the outside through two air supply holes on the outside of the circular vane in the second housing,

The oscillating body and the second housing that rotates together with the rotating shaft are made to have a cam motion stable according to the rotation of the rotating shaft by the rotation restraint.

Circular operating holes formed symmetrically on both sides of the oscillator to change the closed volume of the two separate compression chamber in accordance with the cam motion of the circular operating hole between the second housing and the circular vane to compress a lot of air,

Compressed air compressed in the two compression chambers and collected into one compression chamber through the moving hole of the oscillator is moved to the air storage chamber through the discharge hole of the second housing and then collected in the casing through the compressed air discharge port. and,

Inside the both ends of the ring-shaped operation hole formed in one end of the ring-shaped operation hole is attached to the protruding contact protrusions to maintain some airtight while forming a groove for preventing scratches on both outer surfaces of the circular vanes in contact with the first and second housings Airtightness is maintained during stable cam movement inside the oscillator so that high pressure compressed air can be generated with high compression efficiency in a small space.

Description

Compact Compressor {.}

The present invention relates to a compact compressor, and in particular, the other side of the oscillator receiving the rotational force of the rotating shaft to form a ring-shaped operation hole coupled to the contact protrusions on the inner surface of both ends, the one end is formed with a through hole for the inflow of air The circular vane into which the ring-shaped operation hole is fitted forms a groove to stably compress the air supplied from the outside to be discharged to the discharge hole of the circular vane. The ring-shaped operation hole is formed symmetrically on both sides to compress in two spaces. The present invention relates to a compact compressor capable of producing a large amount of highly efficient compressed air in a small size and allowing for smooth operation.

In addition, the present invention is an improved version of the compact compressor filed on April 23, 1999 of the applicant, a stable contact is not made when the circular operating hole and the circular vane is contacted, the compressed air is moved to an uncompressed space It is prevented from occurring.

That is, the applicant of the present application is that the rotating shaft rotated by the motor at the lower end of the inside of the casing is inserted into the shaft hole of the first housing so as to rotate stably,

The D-shaped rotary shaft, which is the end of the rotary shaft, is inserted into the D-shaped shaft hole to form a ring-shaped working hole on the other side of the swinging body, while the inner side of the rotary gear is integrally formed with a circular space provided on the inner circumferential surface thereof.

In the second housing coupled to the first housing, a ring gear is formed on an inner circumferential surface of the circular space in contact with the circular space in an eccentric state.

Combination of the rotation suppressor so that both gears are engaged with ring gears in the circular space of the oscillator and the second housing, so that the cam motion is stabilized while the oscillator is supported at the center of the second housing according to the rotation of the rotation shaft. and,

The circular compression chamber of the second housing is integrally formed with a circular vane fitted into the ring-shaped operation hole while being connected through the recess to compress the air supplied through the air supply hole formed on the left side of the recess of the second housing. Discharge to the discharge hole formed on the right side of the recess of the circular vane,

After moving to the circular space through the discharge hole it is to be collected in the interior of the casing through the compressed air discharge port.

However, in the conventional compact compressor as described above, when the cam moves by 90 ° while the circular vane is inserted into the ring-shaped operating hole of the swinging body by the rotating shaft, the uncompressed space is formed between the ring-shaped working hole of the swinging body and the second housing. Air is continuously introduced through the air supply hole formed by the outer surface of the circular vane, and when the oscillator cams by 180 °, the air in the compression space of the compression chamber is divided into a compression space, an uncompressed space, and a completely compressed space. When the oscillator is cam-driven by 270 °, the compressed air in the fully compressed space is discharged into the circular space through the discharge hole and collected in the casing through the compressed air discharge port. Compressed air during compression may occur because the ends of the circular vanes cannot be stably contacted with both ends of the There was a disadvantage in that the compression efficiency is lowered by leaking into the uncompressed space.

And there is a problem that one side of the ring-shaped operation hole becomes a vacuum when the section acts as a load to attract the air to interfere with the inflow of air.

Accordingly, the present invention is formed on the other side of the oscillator receiving the rotational force of the rotary shaft to form a ring-shaped operation hole coupled to the contact protrusions on the inner surface of both ends, the through-hole for inflow of air at one end The circular vane into which the ring-shaped operating hole is fitted forms a groove to stably compress the air supplied from the outside to be discharged to the discharge hole of the circular vane, and the ring-shaped operating hole is formed symmetrically on both sides so that compression is performed in two spaces. It is an object of the present invention to provide a compact compressor capable of producing a large amount of highly efficient compressed air in a small size and allowing smooth operation.

The present invention for achieving the above object is such that the air supplied from the outside through the two air supply holes formed on the outside of the circular vane in the second housing to be respectively introduced into the compression chamber of the second housing,

A circular space having a ring gear is formed at the center of the upper end of the second housing while a circular space having a ring gear is formed at an inner circumferential surface at the center of the other side of the swinging body which is inserted into the D-shape hole. And the sun gears formed on both sides of the rotational restraint are engaged with the ring gears so that the cam motion is made stable according to the rotation of the rotation shaft.

Since the circular actuation hole formed symmetrically on both sides of the oscillator is smaller than the compression chamber which is the inside of the second housing and larger than the circular vane connected to the second housing through the recess, the compression is separated into two according to the cam motion of the circular actuation hole. Change the seal volume of the seal to compress a lot of air,

Compressed air compressed in each of the two compression chambers and collected into one compression chamber through the moving hole of the swinging body moves to the air storage quality through the discharge hole formed inside the circular vane of the second housing, and then the compressed air discharge port is opened. To collect inside the casing,

The inside of both ends of the ring-shaped operation hole formed with a through hole for the inflow of air at one end is attached to the contact protrusions to maintain some airtight while maintaining good airtightness, while both sides of the circular vanes in contact with the scratches to prevent scratches The airtightness is maintained during the stable cam movement of the oscillator inside the first and second housings so that high pressure compressed air can be generated with high compression efficiency in a small space.

1 is a side cross-sectional view showing a configuration according to an embodiment of the present invention.

Figure 2 is a plan sectional view showing a configuration according to an embodiment of the present invention.

3 to 5 is a schematic diagram showing in sequence the operating state according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1: casing 2: rotating shaft

3: weight 5: first housing

11: Oscillator 13, 13a: Ring-type working hole

16: moving hole 17: through hole

18, 19: contact protrusion 21: the second housing

34, 35: scratch prevention groove

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 schematically show the configuration of the present invention,

The rotating shaft 2 which rotates by the lower motor not shown in the figure inside the casing 1 and is subjected to the centrifugal force by the weight 3 on one side to enable stable rotation is the shaft hole of the first housing 5. 6) to rotate stably,

On both sides of the swinging body 11 in which the D-shaped rotary shaft 4, which is the end of the rotary shaft 2, is fitted into the D-shaped shaft hole 12 and rotates together, the ring-shaped operating holes 13 and 13a are symmetrically formed therein. In the ring gear 15 is formed integrally with the circular space 14 provided on the inner peripheral surface,

In the second housing 21 coupled to the first housing 5, a ring gear 23 is integrally formed on the inner circumferential surface of the circular space 22 in contact with the circular space 14 in an eccentric state.

In the circular spaces 14 and 22 of the oscillator 11 and the second housing 21, the rotation restraints 31 are engaged with the sun gears 32 and 33 on both sides of the ring gears 15 and 23. ) Is coupled to ensure that the cam motion is stable while the oscillating body 11 is supported at the center of the second housing 21 in accordance with the rotation of the rotary shaft (2),

The circular compression chamber 24 of the second housing 21 is integrally formed by integrally forming a circular vane 26 connected to the ring-shaped operating holes 13 and 13a while being connected through the recess 25. Compress the air supplied through each of the air supply holes 27 and 27a formed on the outer side of the recess 25 of the housing 21,

The circular vane 26 by moving the compressed air compressed in the compression space by the ring-shaped operating hole 13 to the compression space by the ring-shaped operating hole 13a received through the moving hole 16 of the swinging body 11. Is formed on the right side of the concave portion 25 to discharge to the discharge hole 28 to prevent backflow by the valve 28a,

After moving to the air storage chamber 29 through the discharge hole 28 to be collected inside the casing 1 via the compressed air discharge port 30,

Protruding contact protrusions (18) (19) for a certain degree of good contact inside the both ends of the ring-shaped operation hole (13) (13a) formed with a through hole 17 for inflow of air at one end Cams in which the oscillator 11 is stabilized in the first and second housings 5 and 21 by forming scratches 34 and 35 on both outer surfaces of the circular vanes 26 which are formed to be in contact with each other. Airtightness is maintained during the movement, so that high pressure compressed air can be generated with high compression efficiency in a small space.

The compact compressor of the present invention configured as described above is configured to generate compressed air while being rotated by a motor inside the casing 1 to be used for an external air conditioner.

In the process of compressing air, the rotating shaft 2 which is rotated by the lower motor inside the casing 1 is rotated while being fitted in the shaft hole 6 of the first housing 5 while the D-shaped rotating shaft 4 at the end 4 is rotated. ) Rotates the swinging body (11) fitted in the D-shape hole (12).

In addition, the oscillator 11 has a circular space 14 and 22 with ring-shaped operation holes 13 and 13a positioned between the circular compression chamber 24 and the circular vane 26 of the second housing 21. The sun gear 32, 33 of the rotational restraint 31 is fitted to the ring gear 15, 23 of the () to allow stable cam motion.

That is, as shown in FIG. 2, air is introduced into the uncompressed space A of the circular compression chamber 24 through the air supply hole 27 of the second housing 21, and the rotating shaft 2 ), The oscillator 11 is cam-driven in the clockwise direction by the rotation restraint 31 supported by the second housing 21.

As shown in FIG. 3, when the cam is moved by 90 ° clockwise in a state in which the circular vane 21 is fitted into the ring-shaped operating hole 13 of the oscillating body 11 by the rotation shaft 2, the space is not compressed. (A) is formed by the ring-shaped operating hole 13 of the oscillating body 11 and the outer surface of the circular vane 26 of the second housing 21 while the air continues to flow through the air supply hole 27.

As shown in FIG. 4, when the oscillator 11 cams by 180 °, the circular compression chamber 24 is divided into a compression space B, an uncompressed space A, and a completely compressed space C. The air in the compression space B of is further compressed.

At this time, since the ring-shaped operating hole 13 and the circular vane 26 are not secured by the point contact by the concave portion 25 and airtightness is not secured, the contact formed to protrude into the ring-shaped operating hole 13. While the protrusions 18 and 19 are in stable contact with the outer surface of the circular vanes 26 to ensure airtightness, the cam vanes are excessively formed by the scratch preventing grooves 34 and 35 of the circular vanes 26. Contact to prevent wear.

As shown in FIG. 5, the oscillator 11 is cam-driven by 270 ° and the compressed air of the completely compressed space C is discharged to the air storage chamber 29 through the discharge hole 28 to discharge the compressed air ( 30) to continue to collect inside the casing (1).

Here, the through-hole 17 of the ring-shaped operating hole 13 prevents the compressed air from being discharged through the discharge hole 28 and acts as a load to be attracted, so that stable air can be introduced in the following stroke. Make sure

Therefore, according to the compact compressor of the present invention, the second housing is supplied from the outside through two air supply holes on the outside of the circular vane,

The oscillator and the second housing that rotates together with the rotating shaft are configured to have a cam motion stable by the rotation restraint by the rotation restraint.

The circular operating holes formed symmetrically on both sides of the oscillating body change the closed volume of the two separate compression chambers according to the cam motion of the circular operating holes between the second housing and the circular vane to compress a lot of air.

Compressed air compressed in the two compression chambers and collected into one compression chamber through the moving hole of the oscillator is moved to the circular space through the discharge hole of the second housing, and then collected in the casing through the compressed air discharge port. and,

Inside the both ends of the ring-shaped operation hole formed in one end of the ring-shaped operation hole is attached to the protruding contact protrusions to maintain some airtight while forming a groove for preventing scratches on both outer surfaces of the circular vanes in contact with the first and second housings Airtightness is maintained during stable cam movement inside the oscillator so that high pressure compressed air can be generated with high compression efficiency in a small space.

Claims (2)

The rotary shaft 2 rotated by the motor at the lower end of the casing 1 is fitted into the shaft hole 6 of the first housing 5, In the inner side of the swinging body (11) to rotate as the end of the rotating shaft (2), the ring gear 15 is formed integrally with the circular space 14 provided on the inner peripheral surface, In the second housing 21 coupled to the first housing 5, a ring gear 23 is formed on an inner circumferential surface of the circular space 22 in contact with the circular space 14. In the circular spaces 14 and 22 of the oscillator 11 and the second housing 21, the rotation restraints 31 are engaged with the sun gears 32 and 33 on both sides of the ring gears 15 and 23. ) To make the cam movement, Connected to the circular compression chamber 24 of the second housing 21 while integrally forming a circular vane 26 fitted into the ring-shaped operation holes 13 and 13a, the air supply holes 27 and 27a. In a small compressor to receive air through the The rotating shaft 2 is to enable a stable rotation while receiving the centrifugal force by the weight (3) on one side, On both sides of the oscillator 11, ring-shaped working holes 13 and 13a are symmetrically formed to compress air by circular vanes 26 fitted thereto. The circular vane 26 by moving the compressed air compressed in the compression space by the ring-shaped operating hole 13 to the compression space by the ring-shaped operating hole 13a received through the moving hole 16 of the swinging body 11. Discharge to the discharge hole 28 formed on the right side of the recess 25 of the The compact compressor, characterized in that configured to be collected in the casing (1) through the compressed air discharge port 30 after moving to the air storage chamber 29 through the discharge hole (28). The contact protrusions (18) and (19) of claim 1, wherein the contact protrusions (18) and (19) are formed so that airtightness is maintained inside the both ends while forming a through hole (17) for inflow of air at one end of the ring-shaped operation hole (13) (13a). It is formed to protrude for some time so that the oscillator 11 inside the first and second housings 5 and 21 can generate a high pressure compressed air with a high compression efficiency in a small space during the stable cam movement Compressor.