KR19990027626A - Vane pump - Google Patents

Abstract

The present invention relates to a vane pump, and a fixing groove is formed in the space portion of the central bearing portion receiving the rotational force from the outside, and the fixing rod on the other side of the constant velocity coupling into which the fixing rod of one side is inserted into the fixing groove. A fixing groove formed in the space portion of the inner rotor is inserted to rotate at a constant speed, and a thin ring-shaped clamper having one side is inserted into the circular hole of the inner rotor in triple to allow the vanes of the outer rotor to be inserted into the surface contact. By compressing the air according to the state in which the volume of the compression chamber and the supply chamber is changed while the airtight state is maintained, it is possible to obtain a high-pressure compressed air in a small volume of a simple configuration without generating noise due to a collision.

Description

Vane pump

The present invention relates to a vane pump, and in particular, the inner rotor is inserted into a circular hole of the inner rotor while the inner rotor is rotated at a constant speed with the outer rotor by the rotational force transmitted through the constant velocity coupling in the central eccentric shaft, and the opening on one side is integral. A vane pump in which an operation of compressing air in a compression chamber by a vane fitted to a triple clamper is smoothly performed and noise is not generated due to a collision.

In general, the vane pump is installed in the rotor which rotates eccentrically in the cylindrical cylinder so that at least one vane is reciprocated while receiving the elasticity by the spring so that the vanes that are elastically outward as the rotor rotates contact the inner circumferential surface of the cylinder. It is well known that fluids such as oil or air flowing through the inlet are compressed to be discharged through the outlet.

However, according to the conventional vane pump as described above, the distance between the rotor and the cylinder that rotates around the eccentric rotation axis within the cylinder is closer and farther away, and as the distance is varied, the vanes are applied to the elastic force of the spring. It is configured to protrude outward or push inward while contacting the inner wall of the cylinder. Therefore, if the rotor's rotation speed increases, the vane that protrudes outward rapidly contacts the inner wall of the cylinder and is damaged by contact before pushing inward. There is a disadvantage in that the rotation speed can not be faster, of course, there is a problem such that the material and size of the vane is limited in order to reduce the damage of the vane.

In particular, the present invention is improved Patent Application No. 45563 (Vane Pump) dated September 2, 1997, by inserting a ring-shaped clamper with one side opening in the circular hole of the inner rotor, the vane of the outer rotor is fitted, In the contact with the vane of the clamper by placing the shoe formed with the facing and curved grooves to maintain the airtight by the surface contact to compress the air in accordance with the state of the volume of the compression chamber and the supply chamber changes noise caused by the collision It is necessary to install additional shoes due to the lack of elasticity to maintain air tightness between the vanes by forming one clamper in one configuration so that high pressure compressed air can be obtained in a small volume of simple configuration without being generated. There was this.

Accordingly, the present invention inserts a thin clamp into the circular hole of the inner rotor which receives the rotational force through the constant velocity coupling on the center eccentric shaft in triplicate so that the outer rotor rotates at the same speed so that the vane is inserted at a constant velocity, thereby reducing noise during compression. It is an object of the present invention to provide a vane pump capable of obtaining high pressure compressed air by stable operation without generation thereof.

The present invention for achieving the above object is to form a fixed groove in the space portion of the central bearing portion receiving the rotational force from the outside, the fixed rod of the other side of the constant speed coupling in which the fixed rod of one side is inserted into the fixed groove Therein, a fixing groove formed in the space of the inner rotor is inserted to rotate at a constant speed, and a thin ring-shaped clamper having one side is inserted into the circular hole of the inner rotor in three to insert the vanes of the outer rotor. On the side of the supply chamber where the clamper and the vane come into contact with each other, a part of the supply chamber is cut to improve the stretching force, thereby maintaining airtightness while compressing the air according to the change of the volume of the compression chamber and the supply chamber to prevent noise caused by collision. It is possible to obtain high pressure compressed air in a small volume with a simple configuration.

1 is a cross-sectional view showing the configuration of the inner rotor and the outer rotor of the present invention.

2 to 5 are schematic diagrams showing the operation of the present invention.

Explanation of symbols for main parts of the drawings

4: constant velocity coupling 7: internal rotor

11, 12, 13: clamper 17: external rotor

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

A fixing groove 3 is formed in the space portion 2 of the central bearing portion 1 that receives the rotational force from the outside through a motor not shown in the drawing, and a fixing rod of one side is formed in the fixing groove 3. A fixing groove 9 formed in the space portion 8 of the inner rotor 7 is inserted into the fixing rod 6 on the other side of the constant velocity coupling 4 into which the constant velocity coupling 4 is inserted so as to rotate at a constant speed. A thin ring-shaped clamper (11) (13) (15), one side of which is opened in the circular hole (10), is inserted in three to maintain airtightness, and the clamper (11) (13) (15) described above. At the end of the supply chamber side, protrusions 12, 14 and 16 are integrally formed to cut out a portion to improve the bending force, and the vanes 18 of the outer rotor 17 come into contact with the clampers 11 and 13. The bearing part cover 19 according to the state in which the volume of the compression chamber A and the supply chamber B is changed by the inner rotor 7, the vanes 18, and the outer rotor 17 while being fitted together and rotated together. Ball Compressed air supplied to the compression chamber (A) through the air supply hole 20, and the compressed air storage chamber 22 is formed between the outer surface of the outer rotor 17 and the housing 21 to the outer rotor The compressed air discharged through the discharge hole 23 provided with the non-return check valve 24 of (17) is temporarily configured to be discharged to an external tank after being temporarily stored.

The vane pump of the present invention configured as described above operates a motor not shown in the drawing so that the bearing part 1 rotates so that the fixed rod 5 of one side is fitted into the fixing groove 3 formed in the space part 2 thereof. As the coupling 4 rotates together and the constant velocity coupling 4 rotates, the inner rotor 7 in which the fixing rod 6 of the other side is fitted with the fixing groove 9 of the space 8 is retracted. Compression of air is performed while rotating at constant velocity even in the state eccentric with the part 1, and the operation process is as follows.

The air flowing through the air supply hole 20 of the bearing part cover 19 is ring-shaped clampers 11, 13, 15 inserted into the circular hole 10 of the inner rotor 7 and the self-elasticity. The protrusions 12, 14 and 16 on one side are rotatable while the vanes 18 of the outer rotor 17 are kept tight by the bending force, and the clampers 11, 13 and 15 of the Both sides are in airtight contact with the vanes 18 of the outer rotor 17 and are supplied to the supply chamber B partitioned by the inner rotor 17, the outer rotor 17 and the vanes 18, and then the inner rotor ( 7) and the outer rotor 17 are compressed in the compression chamber (A) in which the volume is changed by the clampers (11) (13) (15) and the vanes (18).

That is, as shown in FIG. 2, air is introduced into the supply chamber B, and the circular shape of the inner rotor 7 receives the rotational force through the constant velocity coupling 4 as the bearing part 1 rotates. The vane 18 is fitted while the ring-shaped clampers 11, 13, 15 inserted in the ball 10 rotate and stably contact with their own elasticity and the protrusions 12, 14, 16 at their ends. The outer rotor 17 is rotated clockwise together.

As shown in Fig. 3, the ring-shaped clampers 11, 13 and 15 inserted into the circular holes 10 of the inner rotor 7 by the bearing part 1 rotate together and are sealed by their elasticity. When the vanes 18 of the outer rotor 17 are also rotated by 90 ° in the clockwise direction, the compression chamber A, which was the supply chamber B, is the outer rotor 17 and the vanes 18 and the inner rotor ( 7) As the sealed volume decreases, the supply chamber B is newly secured and air from the outside is introduced.

At this time, the clampers 11, 13 and 15 inserted into the circular holes 10 of the inner rotor 7 are kept airtight by their elasticity, and the vanes (11) to the clampers 11, 13 and 15 are retained. 18, the outer rotor 17 is rotated some more than the inner rotor 17, but the clamper (11) (13) (15) in which the vanes (18) are inserted is the inner rotor (7). Rotates a few more times in the circular hole 10 so that the vanes 18 of the outer rotor 17 remain fitted, as well as contact the vanes 18 by protrusions 12, 14 and 16 at the ends. The air tightness of the compression chamber A is maintained while maintaining the closed state.

As shown in Fig. 4, when the inner rotor 7 and the outer rotor 17 are rotated by 180 °, the volume of the compression chamber A and the supply chamber B becomes almost equal and the air in the compression chamber A Is further compressed.

At this time, the clampers 11, 13 and 15 inserted into the circular holes 10 of the inner rotor 7 are kept airtight by their elasticity, and the vanes are clamped to the clampers 11, 13 and 15. Since the outer rotor 17 and the inner rotor 7 are rotated in the same state in which the 18 is inserted, the airtightness of the compression chamber A is maintained while the vanes 18 of the outer rotor 17 remain fitted. Keep it.

As shown in Fig. 5, when the inner rotor 7 and the outer rotor 17 are rotated by 270 °, a part of the compressed air compressed in the compression chamber A pushes the check valve 24 for preventing the backflow to discharge the discharge hole. Temporarily stored in the compressed air storage chamber 22 through 23, and then discharged to the external compression tank.

At this time, the clampers 11, 13 and 15 inserted into the circular holes 10 of the inner rotor 7 are separated from the vanes 18 by their own elastic and protrusions 12, 14 and 16. While the airtightness is maintained and the vanes 18 are fitted to the clampers 11, 13 and 15, the outer rotor 17 is in a state of being rotated some less than the inner rotor 7, but the vanes 18 Since the inserted clampers 11, 13 and 15 rotate a little less in the circular hole 10 of the inner rotor 7, the compression chamber is maintained while the vanes 18 of the outer rotor 17 remain fitted. A) keep confidential.

When the inner rotor 7 and the outer rotor 15 are rotated 360 ° while being rotated as shown in Fig. 2, the discharge of the compressed air is completely performed and new air is introduced into the supply chamber B. .

In the above embodiment, the protrusions 11, 13, 15 are formed integrally with the protrusions 12, 14, 16 at the ends of the clamp 11 during operation by improving the bending force to bend and unfold. 13) (15) is kept in contact with the vanes 18 while the wear is worn while the airtightness is maintained.

Therefore, according to the vane pump of the present invention, fixing grooves are formed in the center bearing portion and the inner rotor space receiving the rotational force from the outside so that the fixed rod rotates at constant speed by the constant velocity coupling formed on both sides. In the circular hole of the inner rotor, a thin ring-shaped clamper is inserted into the triple hole so that the vanes of the outer rotor are inserted while being kept airtight by elasticity, so that the noise of the collision is not generated, and the high pressure is achieved at a small volume of a simple configuration. To get compressed air.

Claims (1)

The constant velocity coupler is formed in the space part 2 of the central bearing part 1 which receives the rotational force from the outside, and the fixing rod 5 of one side is inserted into the fixing groove 3 of the constant velocity coupler. A fixing groove 9 formed in the space 8 of the inner rotor 7 is inserted into the fixing rod 6 on the other side of the ring 4 so as to rotate at a constant speed, and the circular hole of the inner rotor 7 10. In the vane pump configured to rotate the vanes of the outer rotor 17 so that the vanes are rotated together, the protruding portions 12 and 14 are formed by cutting a part of the circular hole 10 of the inner rotor 7 on the supply chamber side. 16 is integrally formed and the ring-shaped clampers 11, 13 and 15, which are opened at one side, are inserted in a triple manner so that the vanes 18 of the outer rotor 17 are fitted. Vane pump.