JPH0674163A - Ball plunger type rotary pump - Google Patents

Abstract

PURPOSE:To reduce the cost with a simple structure by improving the processability without degrading characteristics. CONSTITUTION:With an axis O2 eccentric to the axis O1 of a guide ring 3 in a casing 2 provided with a cylindrical pump room 10, plural guide tubes 6 of the same type are passed through a rotor 4 fixed at a driving shaft 9 in a radial direction, and respective spherical bodies 7 are inserted in the guide tubes 6. The respective spherical bodies 7 receives centrifugal force by the rotation in an arrowed direction P of the driving shaft 9, and the spherical bodies 7 travel on the guide ring 3 while it is coming into contact with the guide ring 3. The traveling spherical bodies 7 change a volume which is constituted of the outer peripheral surface of a valve tube 8 and the guide 6 stuck to the casing 2, and sucking is carried out by volumetrical expansion at the right half in an eccentric axis direction M1-M2, while discharging is carried out by volumetrical decrease at the left half.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to rotary pumps, and more particularly to the structure of rotary pumps having a ball plunger.

[0002]

2. Description of the Related Art A constant displacement pump is constructed by the movement of a closed space generated between a casing and a rotor inscribed therein.
The discharge amount per one rotation is constant regardless of the load pressure, and the vane pump is also a kind of constant displacement pump.
It is classified as a rotary pump.

FIG. 5 is a view for explaining the structure of a conventional constant-volume vane pump, in which 30 is a vane pump, 31 is a casing, 32 is a pump chamber, 33 is a suction port, and 34 is a discharge port. , 35 is a rotor, 36 is a drive shaft, 37
Is a groove and 38 is a vane.

The vane pump 30 comprises a casing 31 having a pump chamber 32, and a rotor 35 having a vane 38 and eccentrically supported by the casing 31.
That is, the casing 31 has a pump chamber 32 which is a closed cylindrical hollow chamber, and the suction port 33 and the discharge port 34 are arranged in the pump chamber 32 at positions facing each other on the cylindrical surface. The rotor 35 has a drive shaft 36 eccentric to the pump chamber 32.
A cylindrical body having a cylindrical outer diameter smaller than that of the pump chamber 32, and a plurality of grooves 37 radiating through both end surfaces thereof are arranged in a radial direction. The vanes 38 are inserted.

When the rotor 35 rotates in the direction of arrow R by driving the drive shaft 36, the vanes 38 continue to rotate while sliding on the cylindrical wall surface of the pump chamber 32 due to centrifugal force. Since the drive shaft 26 is coaxial with the rotor 35 and is eccentric to the shaft of the pump chamber 32, the rotation of the drive shaft 36 causes the pump chamber 3 to rotate.
The space Q formed by the inner wall surface of 2, the vane 38, and the rotor 35 continues to increase until the line connecting the rotor 35 on the suction port 33 side and the axis of the pump chamber 32, and the fluid flows from the suction port 33 side. The space on the discharge side 22 is sucked in, and on the contrary, the space on the discharge side 22 is continuously reduced, so that the fluid is discharged from the discharge port 34. The vane pump 30 configured as described above has the advantages that when the drive shaft 36 is rotated at a constant speed, the discharge volume does not change even when the discharge pressure changes, and the volume efficiency is good. The groove processing for processing the radial grooves 27 on the rotor 25 is inefficient, and the processing man-hours of the vane pump are large, so that an inexpensive pump cannot be provided.

[0006]

[Objective] The present invention has been made in view of the above-mentioned circumstances,
The purpose of the present invention is to provide a rotary pump that has the same performance as a vane pump and is inexpensive.

[0007]

In order to achieve the above object, the present invention provides (1)
A casing having a cylindrical pump chamber with both end surfaces closed, a drive shaft that is rotatably supported by both end faces of the casing and rotates eccentrically with the pump chamber, and an outer peripheral surface fixed to the drive shaft in the eccentric direction is the pump. An annular body that almost contacts the chamber cylindrical wall,
A rotor having a plurality of circular holes of the same shape arranged in the radial direction, a spherical body movably inserted into each circular hole of the rotor in a liquid-tight manner, and an outer peripheral surface fixed to one end surface of the casing and the rotor. An inner peripheral surface is an annular body that can move in a liquid-tight manner with the drive shaft, and a concave portion is formed in each outer peripheral surface sandwiching the eccentric shaft of the annular body, and the concave portion penetrates one end surface of the casing. And a valve cylinder communicating with the discharge port, and (2) in (1), a hard guide ring fitted and fixed to the pump chamber of the casing is disposed in the pump chamber of the casing. Further, (3) In the above (1) or (2), a hard guide tube for inserting a spherical body in a liquid-tight manner so as to be movable in a liquid-tight manner is fitted and fixed in the circular hole of the rotor,
(4) In the ball plunger rotary pump according to any one of (1) to (3) above, in which the casing and the guide ring are formed separately, the casing is on a line connecting the guide ring and the drive shaft of the rotor. Variable capacity adjusting means for moving the guide ring along the line, and a casing for supporting the guide ring in a casing on the axis facing the variable adjusting means. The amount of eccentricity between the guide ring and the rotor is variable, and further, (5) in any one of (1) to (4), the sphere has a hemispherical shape only in a portion in contact with the cam ring of the sphere, A rod-shaped body that moves densely in a circular hole, and further, (6) in any one of the above (1) to (5), the inside of the rod-shaped body having one end having a hemispherical shape is hollow. Do Than it is. Embodiments of the present invention will be described below with reference to the drawings.

FIGS. 1 (a) and 1 (b) are structural views for explaining a ball plunger type rotary pump according to the present invention. FIG. 1 (a) is a view taken along the line N--N of FIG. b) is a view taken along the arrow M ₁ -M _{3 in} FIG. 1A, in which 1 is a ball plunger type rotary pump, 2 is a casing, 3 is a guide ring, 4 is a rotor, 5 is a circular hole, 6 is a guide cylinder, 7 is a sphere, 8 is a valve cylinder, 9 is a drive shaft, 10 is a pump chamber, 11 is a suction recess, 12 is a suction port, 13 is a discharge recess, and 14 is a bearing. In addition, in order to clarify the structure more, the gap of the rotating portion is illustrated in an enlarged manner more than necessary.

In the figure, the casing 2 has end faces 2a, 2
It is a cylindrical body having a cylindrical pump chamber 10 with a closed axis a and an axis O ₁ as an axis. Further, the pump chamber 1 of the casing 2
At 0, a guide ring 3 made of a hard material and having a uniform thickness is fitted. If the material of the casing 2 is hard, the guide ring 3 is not always necessary. Also,
On both end surfaces 2a, 2a of the casing 2, there is an eccentric shaft O ₂ at a position separated from the shaft O ₁ of the pump chamber 10 by a distance d,
Bearings 14, 1 for supporting the drive shaft 9 with O ₂ as the axis
4 are provided. The rotor 4 is fixed to the drive shaft 9. The rotor 4 is an annular body fixed to the drive shaft 9 via the disc portion 4a, and has a plurality of circular holes 5 of the same shape in the radial direction.
Through, and the guide cylinder 6 is press-fitted into the circular hole 5. If the rotor 4 is made of a hard material, the guide cylinder 6 is not always necessary. The outer peripheral surface of the rotor 4 is close to the guide ring 3 so as to substantially contact the guide ring 3 in the eccentric axial direction M ₁ -M ₂ portion, and increasing the eccentric amount increases the volumetric efficiency. A spherical body 7 that is liquid-tightly movable on the shaft is fitted in the guide cylinder 6.

The inner peripheral wall surface 4b of the rotor 4 is in contact with the outer peripheral surface of the valve cylinder 8a with a gap movable in a liquid-tight manner with the valve cylinder 8. The valve cylinder 8 is a fixed member that is fixed to one end surface 2a of the casing 2 at one end surface, is an annular ring coaxial with the drive shaft 9, and has the drive shaft 9, the rotor 4, and the inner peripheral wall surface 4b as described above.
Has a small gap to the extent that it can be sealed, and similarly both end faces have a small gap with the end face 2a of the casing 2. Further, a suction concave portion 11 and a discharge concave portion 13 are bored in a circumferential direction at positions axially symmetrical to the eccentric axial direction M ₁ -M _2, and the suction concave portion 11 communicates with the suction port 12 of the casing end face 2 a and the discharge concave portion 1
3 communicates with a discharge port (not shown).

Next, the operation of the ball polander type rotary pump 1 having the above structure will be described. When the drive shaft 9 rotates in the direction of arrow P, the rotor 4 also rotates with the drive shaft 9.
The spherical body 7 inserted into the rotor 4 is sealed in the guide cylinder 6 while contacting the guide ring 3 by the centrifugal force accompanying the rotation, and moves on the guide ring 3. For the sake of explanation, A, B, C, D and E are entered on the sphere 7 in correspondence with the position. Guide cylinder 6 and sphere 7 of A on the eccentric axis direction M ₁ -M ₂
The volume V _A formed by the valve cylinder surface 8a and the valve cylinder surface 8a is constant by being closed by the valve cylinder surface 8a, but when a part of the guide cylinder 6 reaches the suction recess 11 by the rotation of the rotor 4, the sphere 7 of B is formed. Since the volume V _B of the fluid is continuously increased, the fluid is sucked from the suction recess 11. Similarly, the volume V C of the sphere 7 of _C continues to increase,
Aspirate fluid. The volume V C of the sphere 7 of _C becomes the maximum, and when the rotor 4 continues to rotate further, the volume V _C becomes
The valve cylinder surface 8b is closed. In the rotation of the rotor 4,
The suction operation is performed in the right half of the eccentric axis direction M ₁ -M ₂ .

The volume V _C closed by the valve cylinder surface 8b further rotates to reach the position of the spherical body V _D of D, and begins to decrease when opening to the discharge concave portion 13, and further decreases at the position of the spherical body E of E. And is discharged from the discharge recess 13 to a discharge port (not shown). That is, in the rotation of the rotor half in the left half in the eccentric axis direction M ₁ -M ₂ , the fluid sucked in in the right half is discharged, and the pump action per rotation of the rotor 4 is performed. By the rotation of the rotor 4 are continuous, rotation times fluid transfer volume (V _C -V _A) is carried out.

FIG. 2 is a view for explaining another embodiment of the ball plunger type rotary pump according to the present invention, in which 15 is an adjusting cylinder, 16 is a piston, 17 is a spring, and 18 is a spring.
Is a volume adjusting handle, 19 is a screw, and the parts having the same functions as those in FIG. 1 are denoted by the same reference numerals as those in FIG.

The adjusting cylinder 15 and the screw 19 are provided in the casing 2.
Disposed in the respective upper and lower positions on the eccentric axis M ₁ -M _2, the guide ring 3 is eccentric axis M ₁ separately from the casing 2 -
It is arranged so as to be movable in the direction of arrow M on M ₂ . That is, the guide ring 3 is vertically movably supported by a screw 19 with M ₂ side, a piston 16 which moves on the shaft in the sliding surface 15a of the guide ring 3 side of the adjusting cylinder 15 at M ₂ side, the spring 17 Volume adjustment handle 18 having screw 18a through
By changing the eccentricity d between the shaft O ₁ of the guide ring 3 and the shaft O ₂ of the rotor 4 to change the volume per rotation (V _C −V _A ) of the rotor 4 to change the ball plunger of the variable volume. Shaped rotary pump.

FIG. 3 is a view showing another embodiment of the sphere according to the present invention, in which 20 is a rod-shaped sphere, 21 is a hemisphere, and 22.
Is the end face. The rod-shaped spherical body 20 has a hemispherical portion only in the portion 21 that comes into contact with the guide ring 3, has an end face 22, and has a diameter φ so that it can move in a liquid-tight manner in the guide barrel 6.
It is a rod-shaped sphere having a diameter substantially equal to, and the sealing property is improved as compared with the sphere.

FIG. 4 is a view showing still another embodiment of the sphere according to the present invention, in which 23 is a rod-shaped sphere, 24 is a hemisphere,
Reference numeral 25 is a hollow portion. The rod-shaped spherical body 23 having the same shape as that shown in FIG. 3 has a hemisphere 24, and a hollow portion 25 is formed inside to form a thin plate-shaped rod-shaped spherical body 23, which has a higher sealing property than the spherical body 7 and is lightweight. Improves responsiveness and improves pump efficiency.

[0017]

As is apparent from the above description, according to the present invention, all the machining of the rotor 4, especially the machining of the plurality of circular holes 5, makes radial circular holes 5 in the rotor 4. Since the number of man-hours required for groove machining is extremely small and a commercially available sphere can be used in place of the vane, it is possible to provide an inexpensive rotary pump having excellent volumetric efficiency.

[Brief description of drawings]

FIG. 1 is a structural diagram for explaining a ball plunger type rotary pump according to the present invention.

FIG. 2 is a view for explaining another embodiment of the ball plunger type rotary pump according to the present invention.

FIG. 3 is a diagram showing another embodiment of the sphere according to the present invention.

FIG. 4 is a view showing still another embodiment of the sphere according to the present invention.

FIG. 5 is a diagram for explaining the structure of a conventional constant displacement vane pump.

[Explanation of symbols]

1 ... Ball plunger type rotary pump, 2 ... Casing,
3 ... Guide ring, 4 ... Rotor, 5 ... Circular hole, 6 ... Guide cylinder, 7 ... Sphere, 8 ... Valve cylinder, 9 ... Drive shaft, 10 ... Pump chamber, 11 ... Suction recess, 12 ... Suction port, 13 ... Discharge recess,
14 ... Bearing, 15 ... Adjusting cylinder, 16 ... Piston, 1
7 ... Spring, 18 ... Volume adjustment handle, 19 ... Screw.

Claims (6)

[Claims] 1. A casing having a cylindrical pump chamber whose both end faces are closed, a drive shaft which is rotatably supported by both end faces of the casing and eccentrically rotates with respect to the pump chamber, and an eccentric direction fixed to the drive shaft. A rotor having an outer peripheral surface substantially in contact with the cylindrical wall of the pump chamber, in which a plurality of circular holes of the same shape are arranged in the radial direction, and a spherical body movably inserted into each circular hole of the rotor in a liquid-tight manner. An annular body fixed to one end surface of the casing and having an outer peripheral surface liquid-tightly movable with the rotor and an inner peripheral surface with the drive shaft, and concave portions on the outer peripheral surfaces sandwiching the eccentric shaft of the annular body. And a valve cylinder communicating with the suction port and the discharge port, the recess having a recess and a valve cylinder communicating with the discharge port. 2. The ball plunger type rotary pump according to claim 1, wherein a hard guide ring fitted and fixed to the pump chamber is provided in the pump chamber of the casing. 3. The ball plunger type according to claim 1, wherein a hard guide tube for inserting a sphere in a liquid-tight manner so as to be movable in a liquid-tight manner is fitted and fixed in a circular hole of the rotor. Rotary pump. 4. The ball plunger rotary pump in which a casing and a guide ring are separately formed, and is movably disposed on the casing on a line connecting the guide ring and a drive shaft of a rotor, and the guide ring is provided. A variable capacity adjusting means for moving the guide ring on the line, and a supporting means for supporting the guide ring in a casing on the axis line facing the variable adjusting means are provided, and an eccentric amount between the guide ring and the rotor is changed. Claim 1 characterized in that
4. The ball plunger type rotary pump according to any one of 3 to 3. 5. The spherical body according to claim 1, wherein only a portion of the spherical body which is in contact with the cam ring has a hemispherical shape and is a rod-like body which moves densely in a circular hole. Ball plunger type rotary pump. 6. The ball plunger type rotary pump according to claim 1, wherein the inside of a rod-shaped body having one end having a hemispherical shape is hollow.