KR101230044B1 - Gerotor pump - Google Patents

Abstract

PURPOSE: A gerotor pump is provided to reduce frictional force between an outer rotor and a casing by forming a compressive chamber in a casing in which power is applied to the outer rotor by fluid pressure. CONSTITUTION: A gerotor pump comprises a lower casing(100), an upper casing(200), a gerotor(300), and a flexible plate. In the lower casing, a suction path connected to an inlet(110) is formed on the upper side. The upper casing is combined to the upper side the lower casing and comprises an outlet path connected to an outlet(210) is formed on the lower side. In the upper casing, a compressive chamber(P) is formed towards an outlet chamber, and the compressive chamber is connected to the outlet of the upper casing. The gerotor is admitted between the upper and lower casings and is engaged so that internal rotor(310) and outer rotor can be spun eccentrically. The flexible plate is combined in the upper side of the gerotor and is comprised of flexible materials in order to be selectively formed outlet paths by internal pressure of the gerotor.

Description

Gerotor pump

The present invention relates to a gerotor pump, and more particularly, to an inner rotor connected to a drive shaft of a motor to transmit rotational force, an outer rotor configured outside the casing, and a casing in which the rotors are accommodated and an inlet and an outlet are formed. In a rotor rotor pump which pumps fluid by forming several closed pumping chambers while the two rotors are eccentrically rotated with a certain gap, a casing in a direction in which a force acts on the external rotor by the pressure of the fluid. The present invention relates to a gerotor pump capable of improving the performance and efficiency of a pump by forming a pressure chamber in the pressure canceling force and reducing friction between the external rotor and the casing.

Gerotor pump is a representative volumetric pump whose flow rate changes in proportion to the rotational speed of the motor. It is composed of an inner rotor and an outer rotor connected to the drive shaft of the motor to transmit rotational force. The two rotors are eccentrically spaced and rotated to form several closed pumping chambers to pump fluid.

That is, the rotors rotate about their respective central axes, and the pumping chamber is enlarged along the rotational direction on the suction side, and the fluid is discharged at a uniform flow rate while being smaller on the discharge side.

More specifically (see Korean Patent Registration No. 10-0695934), as shown in FIG. 1, the internal rotor 10 of the general rotor rotor pump has N lobes 11 formed on the outside thereof, and the outer rotor 20 has N + inside thereof. One lobe 21 is formed so that the lobes 11 and 21 are engaged to rotate with a rotation ratio of (N + 1) / N.

The rotors 10 and 20 rotate with a certain eccentricity, and the eccentricity makes a pumping chamber A capable of transferring the fluid fuel between the inner rotor 10 and the outer rotor 20.

2, the inner rotor 10 and the outer rotor 20 are seated in the casing 30, and the suction passage 31 and the discharge passage 32 are formed in the casing 30 so as to be symmetrical with each other. The sealing plate 40 is in close contact with the upper portions of the rotors 10 and 20.

Thus, the pumping chamber A repeatedly increases and decreases the volume while the rotors 10 and 20 are rotated, so that the portion where the volume is increased becomes a vacuum state and fluid is sucked through the suction flow path 31. In the portion where the volume decreases, the pressure is increased to discharge the fluid through the discharge passage 32.

However, in the pumping chamber (A), the force to pull the outer rotor 20 at the portion where the pressure decreases as the volume increases, and to push the outer rotor 20 outward at the portion where the pressure increases as the volume decreases. Force is at work

As a result, frictional force is increased in the contact surface between the outer rotor 20 and the casing 30, thereby degrading the performance of the pump and causing wear and shortening the service life.

KR 10-0695934 B1 (2007.03.09)

The present invention has been made to solve the above problems, an object of the present invention is connected to the drive shaft of the motor and the inner rotor for transmitting the rotational force and the outer rotor and the rotor is configured to receive the inlet and discharge port In a rotor pump comprising a casing in which the two rotors are eccentrically rotated with a predetermined gap to form a plurality of closed pumping chambers and pump the fluid, the force is applied to the external rotor by the pressure of the fluid. The pressure chamber is formed in the casing in the acting direction to cancel the force, thereby providing a gerotor pump capable of reducing friction between the external rotor and the casing.

Gerotor pump of the present invention for achieving the above object, the lower casing 100 is formed on the upper surface of the suction flow path 120 is in communication with the inlet 110 formed on one side; An upper casing 200 coupled to an upper side of the lower casing 100 and having a discharge flow path 220 communicating with a discharge port 210 formed at one side thereof at a lower surface thereof; And a rotor (300) accommodated between the lower casing (100) and the upper casing (200), wherein the inner rotor (310) and the outer rotor (320) are engaged to eccentrically rotate; It is made, including the upper casing 200, the pressure chamber (P) is formed on the discharge chamber (D) side of the inner peripheral surface in contact with the outer rotor 320, the pressure chamber (P) is the upper casing ( It is characterized in that the communication with the discharge port 210 of the 200.

In addition, the gerotor pump of the present invention, the upper casing is formed, the lower casing 100 is formed on the upper surface of the suction flow path 120 is in communication with the inlet 110 formed on one side; A rotor (300) accommodated in the lower casing (100) and engaged with the inner rotor (310) and the outer rotor (320) to be eccentrically rotated; And a flexible plate 400 coupled to an upper surface of the gerotor 300 and made of a flexible material so that the discharge passage 410 is selectively formed by the internal pressure of the gerotor 300. The lower casing 100 may include a pressure chamber P formed at a discharge chamber D side of the inner circumferential surface of the inner casing in contact with the outer rotor 320, and the pressure chamber P may have a discharge passage ( And 410).

The rotor pump of the present invention forms a plurality of closed pumping chambers while the two rotors are eccentrically rotated with a certain gap, so that the casing in a direction in which a force acts on the external rotor by the pressure of the fluid when the fluid is pumped. By forming a pressure chamber to cancel the force to reduce the friction between the outer rotor and the casing, there is an advantage that can improve the performance and efficiency of the pump.

1 is a cross-sectional view showing an inner rotor and an outer rotor of a conventional rotor pump.
Figure 2 is a cross-sectional view showing a conventional gyro pump.
Figure 3 is a cross-sectional view showing a gyro pump of the present invention.
Figure 4 is a cross-sectional view showing a pressure chamber formed in the casing according to the present invention.
5 is a cross-sectional view showing another example of the gerotor pump of the present invention.

Hereinafter, the Gerotor pump of the present invention as described above will be described in detail with reference to the accompanying drawings.

3 is a cross-sectional view showing the gerotor pump of the present invention.

As shown, the gerotor pump of the present invention includes: a lower casing 100 having a suction flow path 120 communicating with an inlet port 110 formed at one side thereof on an upper surface thereof; An upper casing 200 coupled to an upper side of the lower casing 100 and having a discharge flow path 220 communicating with a discharge port 210 formed at one side thereof at a lower surface thereof; And a rotor (300) accommodated between the lower casing (100) and the upper casing (200), wherein the inner rotor (310) and the outer rotor (320) are engaged to eccentrically rotate; It is made, including.

At this time, the upper casing 200 is formed with a pressure chamber (P) on the discharge chamber (D) side of the inner peripheral surface in contact with the outer rotor 320, the pressure chamber (P) is the discharge port of the upper casing (200) It is formed to communicate with (210).

First, the lower casing 100 has an inlet 110 formed at one side thereof so as to pass through the upper and lower surfaces thereof, and the suction channel 120 is in the form of a groove so as to communicate with the inlet 110 at the upper surface of the lower casing 100. Is formed.

The upper casing 200 is coupled to be in close contact with the upper surface of the lower casing 100, the inner space is formed on the lower side is configured to accommodate the gerotor 300.

The upper casing 200 has a discharge port 210 formed at one side thereof to penetrate the upper and lower surfaces thereof, and a discharge flow path 220 is formed at the lower surface of the upper casing 200 so as to communicate with the discharge port 210.

Here, the gerotor 300 is accommodated and seated in the inner space of the upper casing 200, and the lower casing 100 and the upper casing 200 are coupled to each other so that the gerotor 300 rotates therebetween. It is composed.

In addition, the lower casing 100 and the upper casing 200 are inserted into the pump housing 600 in a coupled state to fix the outside thereof.

In this case, the gerotor 300 includes an inner rotor 310 and an outer rotor 320, and the inner rotor 310 is configured inside the outer rotor 320.

4, the inner rotor 310 and the outer rotor 320 are engaged to be eccentrically rotated, and the inner rotor 310 is fixed to the shaft 510 of the armature 500 to be rotated. As the inner rotor 310 rotates, the outer rotor 320 is rotated in an eccentric state.

In addition, the number of lobes 311 and 321 of the inner rotor 310 and the outer rotor 320 are different from each other, and the number of lobes 321 of the outer rotor 320 is one more than that of the inner rotor 310. Is formed a lot.

Thus, the fluid is sucked and discharged by the volume change of the space formed between the inner rotor 310 and the lobes 311 and 321 of the outer rotor 320 to be engaged and rotated.

At this time, a plurality of suction chambers I, which are portions that suck fluid while increasing volume, are based on a portion where teeth are completely coupled between the inner rotor 310 and the lobes 311 and 321 of the outer rotor 320. On the contrary, a plurality of discharge chambers D, which are portions for discharging the fluid while the volume is reduced, are formed.

And along the circumferential direction of the rotor 300, the center of the suction chamber (I) and the discharge chamber (D) is formed with a stagnant portion (S) with no change in volume.

That is, due to the difference in the number of lobes 311 and 321 of the inner rotor 310 and the outer rotor 320, the volume change occurs between the lobes 311 and 321 as the rotor 300 rotates to inhale the fluid. And to discharge.

Here, the suction flow path 120 formed in the lower casing 100 may be formed in the form of a groove long in the circumferential direction so as to communicate with the suction chamber (I), the discharge formed in the upper casing 200 The flow path 220 may be formed in the form of a groove long in the circumferential direction so as to communicate with the discharge chamber (D).

Thus, the fluid flows through the inlet 110 of the lower casing 100 and is sucked into the suction chamber I through the suction flow path 120, and is compressed while the volume is reduced in the discharge chamber D. It is discharged to the discharge port 210 through the discharge flow path 220 of the casing 200 is pumped into the pump housing 600.

In this case, due to the vacuum pressure generated while the volume of the suction chamber I increases and the discharge pressure generated while the volume of the discharge chamber D decreases, the internal rotor 310 and the external rotor 320 are specific. Force acts in the direction.

In addition, the inside rotor 310 and the outside rotor 320 are rotated in the upper casing 200 to form the suction chamber I, the stagnant portion S, and the discharge chamber D. Since it is repeatedly formed in a certain area, the force always acts in the same direction.

That is, as shown in FIG. 4, the inner rotor 310 has a force acting in the direction of the suction chamber I when the center is the reference, and the outer rotor 320 has the discharge chamber D when the center is the reference. Force acts in the direction.

At this time, the inner rotor 310 is fixed in the radial direction by the shaft 510 of the amateur 500, the frictional force is small by the force of the pressure of the fluid, but the outer rotor 320 is the Since the radial movement is fixed in contact with the inner circumferential surface of the upper casing 200, the contact area is wide, and the frictional force is largely acted upon by the pressure of the fluid.

Therefore, the friction force can be reduced by reducing the force pushing the outer rotor 320 in the direction of the inner circumferential surface of the upper casing 200 due to the pressure of the fluid.

Here, in the gerotor pump of the present invention, a pressure chamber P is formed at the discharge chamber D side of the inner circumferential surface of the upper casing 200 in contact with the outer rotor 320, and the pressure chamber P is the It is formed to communicate with the discharge port 210 of the upper casing (200).

That is, the pressure passage 230 is formed on one side of the upper casing 200 and the pressure chamber P is formed to communicate with the pressure passage 230, so that the fluid discharged through the discharge port 210 is discharged. It flows into the pressure chamber P along the pressure flow path 230.

Herein, the fluid flows into the pressure chamber P along the pressure passage 230 to maintain a state in which the fluid is filled in the pressure chamber P, and the pressure of the fluid filled in the pump housing 600 and the The pressure of the fluid filled in the pressure chamber P is kept the same.

Thus, the force acting on the external rotor 320 by the pressure of the fluid in the discharge chamber (D) and the force due to the pressure of the fluid introduced into the pressure chamber (P) cancel each other, the external rotor (320) The outer circumferential surface and the inner circumferential surface of the upper casing 200 is in contact with the friction force is reduced.

As described above, the rotor rotor pump of the present invention forms a plurality of sealed suction chambers and discharge chambers while the two rotors are eccentrically rotated with a predetermined gap to force the external rotor by the pressure of the fluid when the fluid is pumped. By forming a pressure chamber in the upper casing of the acting direction, the force is canceled to reduce the friction between the outer rotor and the upper casing, thereby improving the performance and efficiency of the pump.

At this time, the pressure chamber (P) is the area of the pressure chamber (P) formed in contact with the external rotor 320 in order to cancel the force acting on the external rotor 320 by the pressure of the fluid. And the position should be appropriately selected, as shown in the pressure chamber (P) is formed so as to be located in the center portion of the thickness of the outer rotor 320, the circumferential direction to the center portion of the discharge chamber (D) It is preferable that it is formed to be symmetrical with reference.

And another example of the Gerotor pump of the present invention, the upper casing is formed, the lower casing 100 is formed on the upper surface of the suction flow path 120 is in communication with the inlet 110 formed on one side; A rotor (300) accommodated in the lower casing (100) and engaged with the inner rotor (310) and the outer rotor (320) to be eccentrically rotated; And a flexible plate 400 coupled to an upper surface of the gerotor 300 and made of a flexible material so that the discharge passage 410 is selectively formed by the internal pressure of the gerotor 300. The lower casing 100 may include a pressure chamber P formed at a discharge chamber D side of the inner circumferential surface of the inner casing in contact with the outer rotor 320, and the pressure chamber P may have a discharge passage ( It may be formed to communicate with the 410.

This is similar to the former embodiment, but as shown in FIG. 5, the gerotor 300 is accommodated in the lower casing 100, and a flexible plate 400 made of a flexible material is formed on the upper side of the gerotor 300. As the flexible plate 400 is rotated together with the gerotor 300, the flexible plate 400 is selectively opened at a portion where the discharge chamber D is formed to discharge the fluid.

Here, the flexible plate 400 is coupled to be in close contact with the upper surface of the gerotor 300, made of a flexible material and the pressure is increased while the volume inside the discharge chamber (D) is reduced to increase the pressure of the flexible plate 400. The fluid is discharged while a part is opened upward and opened.

That is, the discharge passage 410 is not formed separately, and the flexible plate 400 is opened while being opened upward by the pressure of the fluid inside the discharge chamber D formed in the gerotor 300. The flexible plate 400 on the upper side of the chamber D becomes an open space.

At this time, the pressure chamber (P) is formed in the lower casing (100), the flexible plate 400 is opened to the upper side in the discharge chamber (D) is formed, the discharge passage 410 is formed And the discharged fluid flows into the pressure chamber P along the pressure passage 130 formed in the lower casing 100, and acts on the external rotor 320 as in the former embodiment. Since the pressure due to the pressure in the chamber (D) and the pressure in the pressure chamber (P) cancel each other, it is possible to reduce the frictional force at the contact surface of the outer rotor 320 and the lower casing (100).

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

100: lower casing
110: inlet port 120: suction flow path
130: pressure flow path
200: upper casing
210: discharge port 220: discharge flow path
230: pressure flow path
300: Gerotor
310: internal rotor 311: lobe
320: external rotor 321: lobe
400: flexible plate
410 discharge flow
500: amateur 510: shaft
600: pump housing
I: Suction chamber D: Discharge chamber
P: Pressure chamber S: Stagnation

Claims (2)

A lower casing 100 having a suction passage 120 communicating with an inlet 110 formed at one side thereof, the upper casing 100 being formed on an upper surface thereof;
An upper casing 200 coupled to an upper side of the lower casing 100 and having a discharge flow path 220 communicating with a discharge port 210 formed at one side thereof at a lower surface thereof; And
A girder 300 accommodated between the lower casing 100 and the upper casing 200 and engaged with the inner rotor 310 and the outer rotor 320 to be eccentrically rotated; , ≪ / RTI >
The upper casing 200 has a pressure chamber P formed at the discharge chamber D side of the inner circumferential surface in contact with the outer rotor 320, and the pressure chamber P has a discharge port 210 of the upper casing 200. Gerotor pump characterized in that the communication with.
A lower casing 100 having an upper portion formed to be open and having a suction passage 120 communicating with an inlet 110 formed at one side thereof;
A rotor (300) accommodated in the lower casing (100) and engaged with the inner rotor (310) and the outer rotor (320) to be eccentrically rotated; And
A flexible plate 400 coupled to an upper surface of the gerotor 300 and made of a flexible material so that the discharge passage 410 is selectively formed by the internal pressure of the gerotor 300; , ≪ / RTI >
The lower casing 100 is a pressure chamber (P) is formed on the discharge chamber (D) side of the inner peripheral surface in contact with the outer rotor 320, the pressure chamber (P) is in communication with the discharge flow path (410) Gerotor pump characterized by.

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