KR200267821Y1 - Vane pump - Google Patents

Abstract

The present invention improves the pumping efficiency and improves the pumping efficiency in the vane pump in which the vane pump inserted into the linear circumferential groove formed on the line passing through the rotation center is in contact with the inner circumferential surface of the pump chamber. In order to provide a vane pump, the motor shaft (3) located on one side in the pump chamber (1) blocked by the cover (2) is equipped with a rotor (4) formed with a straight vane groove (5) passing through the center of rotation. The wing groove 5 is inserted into the wing 6, which is always in contact with the inner circumferential surface of the pump chamber 1, the rotor groove in the rotor 4 orthogonal to the wing groove 5 at its rotation center (7), and the blade (6) is divided in half, but at the divided end to form a guide hole (9) for guiding the insertion portion (10) of the other blade (8), the blade groove (7) Half the length is inserted into the guide hole (9) at the divided end It characterized the configuration of a vane pump inserted into the insertion portion 10 is formed to receive the wings (8).

Description

Vane Pump {VANE PUMP}

The present invention relates to a vane pump in which a blade inserted into a wing groove formed on a line passing through a rotation center reciprocates and pumps. In particular, the pumping function is improved in spite of the improvement of pumping efficiency due to the expansion of the blade and the wear of the wing outer end. It relates to a vane pump that is maintained and effectively suppresses pulsation.

The present invention is a technical advance of the vane pumps of the pre-registered headings 238619 and 238620. These prior arts consist of a rotor having a single wing groove formed on a line passing through the center of rotation, and a single wing that is inserted into the wing groove and slides to suck and discharge a liquid material or gel material. The singular wing has a large load and pulsation in the process of sucking and discharging a large amount of liquid or gel material at once, and also affects the pumping efficiency.

In addition, when the outer end of the wing is worn due to friction with the inner surface of the pump chamber, the play increases, but the wing itself cannot compensate for this play, and thus, there is no way to prevent the deterioration of the pumping function unless the wing is replaced.

Therefore, the object of the present invention is to improve the performance of the vane pump that sucks and discharges the liquid material or the gel-like material while being in contact with the inner circumferential surface of the pump chamber on the straight wing groove formed through the rotational center, and functioning even if the outer end of the wing is worn. It is to provide a vane pump that can exert.

The technical problem is to extend the wing groove orthogonal to the existing wing groove at the center of rotation of the rotor, the existing wing is half the length, but the guide hole for guiding by inserting the insertion portion of the wing is extended to the divided end, The vanes are also divided into half lengths, but are inserted into the guide holes at the split ends to guide the inserts. The vanes are inserted into the wing grooves formed so that the inserts face each other, alternately with the existing wings, and are configured to suck and discharge liquid or gel material. Achieve it with a pump.

1 is a longitudinal side view of the vane pump to which the present invention is applied

2 is a perspective view of the rotor and the wing according to the present invention

3 is a longitudinal front view of the pump chamber;

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

1: pump room 4: rotor

5,7: Wing groove 6,8: Wing

9: guide hole 10: insertion unit

In FIG. 1, in the pump chamber 1 clogged with a lid 2, the motor shaft 3 penetrates into the middle between the suction port 11 and the discharge port 12, and the rotor shaft is connected to the motor shaft 3. 4) is inserted, and two types of wings 6 and 8 are inserted into the rotor 4.

In FIG. 2, the rotor 4 is formed with two wing grooves 5, 7. These wing grooves 5 and 7 are all linear and orthogonal at the center of rotation of the rotor 4, and the second wing grooves 7 are added to the existing wing grooves 5. The width of the wing grooves 5 and 7 is also the same.

In the vane pump of this structure, the two blades (6) (8) act in the orthogonal direction on the rotor (4) and alternately take up and discharge. If the two wings (6, 8) are simply orthogonal, they are inoperative. In order not to do this, the two wings 6 and 8 must be able to slide smoothly in their wing grooves 5 and 7 without being interfered with each other. In addition, even if the outer ends of the blades 6 and 8 are worn out due to friction with the inner circumferential surface of the pump chamber 1 during operation and the length is shortened, it is difficult if the pumping action is abnormal.

In consideration of this point, the wing 8 which is inserted into the existing wing 6 and the wing wing 7 which is extended and acts in the wing groove 5 and performs the aspiration and discharge action is expanded. Half of each length gives the room to move each blade (6,8) in the centrifugal direction as the rotor (4) rotates. In addition, at the divided end of the wing 6, a rectangular rectangular guide hole 9 is drilled, and at the divided end of the wing 8, an insertion portion 10 guided by being loosely inserted into the guide hole 9 is formed to form two wings. (6,8) rotates the intake and discharge sections, so that they do not interfere with each other in the intake and discharge operation.

In Fig. 3, the vane 6 is the longest when the vane 6 is on the boundary between the inlet and outlet sections, and the other vane 8 is the remaining liquid phase just before the inlet 12 and the inlet initial stage just past the inlet 11. It is located at the place where the substance or gelled substance is discharged, and the length thereof is the shortest.

Thereafter, this time, even when the other wing 8 comes on the boundary line between the suction section and the discharge section, the length thereof becomes the longest, and the blade 6 is formed at the initial stage just past the suction port 11 and immediately before the discharge port 12. It is located at the place where the remaining liquid material or gelled material can be discharged, so the length thereof is the shortest.

The expansion and contraction of such two wings 6 and 8 is possible because the length of the vertical line in which the wing 6 is located in the pump chamber 1 is longer than the horizontal line in which the wing 8 is extended.

In addition, the wing 6 moves intake stroke and discharge stroke sequentially, and the other wing 8 follows the wing 6, and when such action is performed, the blade 6 moves linearly in the wing grooves 5 and 6 belonging to each other. The inserting portion 10 is guided in the guide hole 9 and the guide hole 9 is guided by the inserting portion 10 but does not interfere with each other.

In addition, over time, the outer ends of the vanes 6 and 8 wear due to friction with the inner circumferential surface of the pump chamber 1, and the length becomes short. Even so, it does not matter until the wings (6, 8) are extremely short in length and become ineffective. This is because when the rotor 94 rotates, the vanes 6 and 8 move in the centrifugal direction by the centrifugal force to come into close contact with the inner circumferential surface of the pump chamber 1.

As the blades 6 and 8 are expanded, the suction amount and the discharge amount per one time are reduced by half compared to those of a single wing, so that pulsation phenomenon, vibration and noise are also significantly reduced.

As described above, a separate wing groove is extended in the orthogonal direction from the center to the linear wing groove formed through the rotation center of the rotor, and the wings in both directions cross each other, and the pumping performance is doubled by repeating the suction and discharge strokes. .

In addition, as the vanes in each direction are divided to give room for the rotor to move in the centrifugal direction due to the centrifugal force when the rotor rotates, even if the outer ends of all the blades are worn due to the friction with the inner circumferential surface of the pump chamber, the inner circumferential surface of the pump chamber is contacted. It can function well until the end of its life.

And while the wings in both directions are orthogonal to each other, the guide grooves and the insert guide the mutual guide action of the two wings are not interfered smoothly without interference.

Claims (1)

The motor shaft 3 located on one side in the pump chamber 1 blocked by the cover 2 is equipped with a rotor 4 having a linear wing groove 5 passing through a rotational center, and the wing groove 5 In the blade 6, which is in contact with the inner circumferential surface of the pump chamber 1 at all times is inserted, the rotor 4 is formed with a wing groove 7 orthogonal to the wing groove 5 at the center of rotation thereof, and the wing (6) is divided into half the length to form a guide hole (9) for guiding the insertion portion 10 of the other wing (8) in the divided end, the wing groove (7) is divided into half the length but the A vane pump, characterized in that the insertion of the end (8) having the insertion portion 10 is inserted into the guide hole (9) is inserted.