KR20030075232A - Vane pump - Google Patents

Abstract

PURPOSE: A vane pump is provided to reduce the cost by lengthening the life span of vanes and reducing the exchange frequency of vanes and to effectively protect a housing from solids of sludge. CONSTITUTION: In a vane pump, a rotor(3) with vanes(4) is installed in a vane groove(9) radially formed to a housing of a motor-built-in body(1) and a cover protects the housing. The housing, having a suction port(a) and a discharge port(b), is separated from the body. On the inner peripheral surface of the housing, a rubber liner(7) is attached to a part except the inside of the suction port and the discharge port. A circular groove(10) is formed in the middle of the rotor. An axially parallel pin(11) is formed to the inner end of the cover side of the vane. A pin guide pipe(13) for maintaining the pumping orbit of the vane concentric to the housing is formed to the inside of the cover, and an annular pillar(14) for maintaining the pumping orbit of the vane is formed to the inner center. An adjusting screw(17) for housing center movement is fastened to a screw hole(16) bored in the middle of a bolt(6) for fastening the body and the cover, with interposing the housing.

Description

Vane pump

The present invention relates to a vane pump for the purpose of suppressing abrasion of the vane outer end due to the sliding contact with the inner circumferential surface of the pump chamber and overcoming the pumping failure due to the solids mixed into the sludge.

The biggest problem with the vane pump is that the blades are easily worn out and the replacement cycle is short, and the inner circumference of the pump chamber of the housing is not long due to friction with the outer edge of the blade. The rotor registration form 267821, in which the rotor blade groove is formed in the + direction and the blade is inserted into each wing groove, is no exception. This is especially true for vane pumps dedicated to sludge pumping in which solids such as stones, wood chips and metal chips are mixed in the fluid.

When the sludge mixed with solids is introduced into the pump chamber, abrasion of the inner edges of the inlet and discharge ports of the housing and the tip of the blades is accelerated due to the collision with the blades, and in some cases, the blade tip may be broken. Solids may also eat up the inner circumferential surface of the pump chamber, reducing pumping efficiency.

Therefore, an object of the present invention is to provide a vane pump that can reduce the cost by increasing the service life of the wing to reduce the replacement frequency, and effectively protect the housing from the solids discharged from the suction by mixing in the sludge.

In order to achieve this problem, the present invention separates the housing in which the outer end of the wing is in constant contact with the motor built-in body, and attaches a rubber liner to the inner circumferential surface of the housing so that the contact with the outer end of the wing is changed from conventional hard contact to soft contact. The vane pump is configured to protect the inner circumferential surface of the housing and the outer end of the blade at the same time, and to form a relatively large space by not attaching a liner to each inner end of the inlet and discharge ports, so that the solids mixed in the sludge are effectively discharged and discharged. Suggest.

In addition, if uneven wear occurs at the tip of the liner of the suction-discharge section, there is also provided a means for simply correcting by moving the center of the housing without replacing the liner.

1 is a perspective view of the vane pump peeling off the cover and only one wing separated from the present invention

2 is a sectional view of main parts of the assembled state;

3 is a partial cutaway front view of the pump unit in a state where the cover is removed from the assembled state;

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

1: main body 2: housing

3: rotor 4: wings

5: cover 6: bolt

7: liner 10: groove

11: pin 13: pin guide

14 ventilation hole 16: screw hole

17: adjusting screw

In Fig. 1, the vane pump proposed in the present invention, like any vane pump, has a bolt having a main body 1, a housing 2, a rotor 3, a wing 4, a cover 5, and a pump chamber center movement control means. It consists of (6).

The housing 2 is separated from the main body 1 to drive the rotor 3 with the motor built in the motor chamber 1b, and the liner 7 is attached to the inner circumferential surface thereof. The liner 7 is made of rubber having low elasticity and excellent tear strength, and is thick. The liner 7 is attached to the entire inner circumferential surface of the housing 2 except for the inner end regions of the inlet port a and the outlet port b. A jaw 7a is erected at both inner edges of each liner 7 to reinforce the adhesion to the inner surface of the main body 1 and the cover 5 during assembly, and a sludge filling groove 7b is provided at one point of the jaw 7a. When forming and pumping the sludge after assembly, the sludge flowing out there is trapped in an enclosed space 8 formed between the jaw 7a and the main body 1 and the cover 5 so as to enclose a zone of the packing 2 ) And the body 1 as well as to enhance the internal watertightness between the housing 2 and the cover 5.

The rotor 3 has the wing groove 9 formed so that the inner end may pass in four directions at the quarter which divided the circumference, and the blade 4 is inserted in each wing groove 9. In the rotor 3, a groove 10 corresponding to approximately half of its thickness is formed concentrically. The groove 10 is a position where the pin guide tube formed on the rear surface of the cover 5 is inserted.

The blade 4 cuts the cover side of the middle half of the length by the depth of the groove 10, and forms the pin 11 at the inner end of the cut-out in parallel with the axial direction and fits the ring 12. The ring 12 makes contact with the inner circumferential surface of the pin guide tube so that the ring pin 11 contacts the inner circumferential surface of the pin guide tube while the blade 4 contacts the inner circumferential surface of the pin guide tube while the blade 4 is turning along the pumping trajectory within the housing 2. By avoiding this, the pumping action of the blade 4 is smoothed, and the task of preventing the wear of the pin 11 and the wear of the inner circumferential surface of the pin guide tube is performed at the same time.

An inner surface of the cover 5 forms a pin guide tube 13 concentrically with the housing 2. The pin guide tube 13 is a pin 11 when the wing 4 passes along the pumping trajectory in the housing 2 and passes through the inner ends of the inlet port (a) and the discharge port (b) to which the liner (7) is not attached. It is to control the wing (4) so as not to deviate from the pumping trajectory even by centrifugal force.

The inner diameter of the pin guide tube 13 is slightly larger than the radius of the pin 11 plus the thickness of the ring 12 outside the radius of the trace drawn by the center of the ring pin 11 when pumping the blade 4 during pumping. By making the outer end of the liner firmly contact the inner circumferential surface of the liner 7, there is no shortage in exerting the pumping function, and at the same time, the end 7c of the liner 7 on the inlet port a and the outlet port b side Minimizes the impact that is likely to occur when passing through the liner 7 of the previous stroke or entering the liner 7 of the subsequent stroke while passing.

When the blade 4 passes through the section where the liner 7 is not present, that is, the inlet port a and the discharge port b, the suction load or the discharge load of the sludge is discharged when the sludge is sucked or discharged. If it is larger than the centrifugal force acting on (4), the blade 4 will be pushed into the wing groove 9, and a gap will be formed between the outer end of the blade 4 and the inner peripheral surface of the housing 2. This causes abnormalities in the suction and discharge functions of the sludge.

In consideration of this point, the ventilation column 14 is formed in the inner center of the pin guide tube 13. The ventilation column 14 is pushed in such a way that the blade 4 is pushed to affect the pumping even if the suction pressure and the discharge pressure of the sludge are greater than the centrifugal force of the blade 4 regardless of the angle at which the blade 4 is positioned. It's a stopper that won't let you. The pin guide tube 13 and the ventilation column 14 is formed slightly lower than the groove 10 of the rotor 3 so as not to interfere with the rotational activity of the rotor 3.

Around the pin guide tube 13 is formed a liner press 15 in the form of a circular protrusion larger than the inner diameter of the liner 7 and smaller than the outer diameter of the housing 2. When pumping, the front end portion 7c of the liner 7 located in the discharge direction at the inner end of the inlet port a may be caught with solids mixed into the sludge between the outer end of the blade 4 passing therethrough. Frequently, the tip 7c of the liner 7 will wear prematurely relative to the rest. The uneven wear of the tip portion 7c of the liner 7 is deeply related to the decrease in pumping efficiency. The thickness of the tip portion 7c of the worn liner 7 is still considerable and may still be used. Nevertheless, replacing the liner 7 immediately is unreasonable.

In this case, when the wear portion occurs on the tip portion 7c while the liner 7 can be continuously used, the tip portion 7c of the wear-like liner 7 is approached toward the rotor 3 to allow contact with the wing 4. If so, the liner 7 can be used for the rest of its life. To this end, it is necessary to move the center of the housing 2 sandwiched between the main body 1 and the cover 5 within a range where the pumping efficiency is maintained.

One of the things to supplement this point is the liner press part 15 mentioned above. The liner pressing part 15 is a circular jaw protruding concentrically on the outer side of the pin guide tube 13 from the inner surface of the cover 5. More specifically, the outer diameter of the liner pressing portion 15 is larger than the inner diameter of the liner 7 so as to maintain the watertightness with respect to the cross section of the liner 7 in spite of the center movement of the housing 2. 2) The outer diameter of the liner pressing portion 15 is smaller than the inner diameter of the housing 2 so as to leave a considerable space between the inner circumference and the center of the housing 2 so that the center of the housing 2 can be moved. Leave the center movement space (S) of). In consideration of the central mobility of the housing 2, the outer diameters of the front face 1a of the main body 1 and the cover 5 should of course be wider than the outer diameter of the housing 2.

And it is also a requirement to have a center moving means that can easily move the center of the housing (2) from the outside in the assembled state of the vane pump. Thus, the main body 1 and the cover 5 are joined to both ends of the housing 2 and fastened with the bolts 6 to maintain the engaged state, so that the screw holes 16 are perpendicular to the middle of the bolts 6. It is configured to move the center of the assembled housing (2) while sandwiching between the body (1) and the cover (5) by inserting the adjustment screw (17).

However, such a liner pressing part 15 may be omitted if it is manufactured so that the length of the liner 7 is increased so that the liner 7 can be completely and tightly fitted between the body 1 and the cover 5.

In FIG. 2, the rear end of the housing 2 with the liner 7 is attached to the front face 1a of the main body 1 so as to surround the rotor 3 and pins 11 for each wing groove 6 of the rotor 3. Into the blade 12, the blade 4 is inserted. At this time, all the wings (4) to the pin (11) to face the cover (5). Then, one end of the bolt 6 is inserted into all the fastening holes 18 of the main body 1, and the nut 19 is fastened. The cover 5 is fitted with the other end of the bolt 6 in its fastening hole 20 while the inner surface of the pin guide tube 13 walks the outside of all the rings 12 so that the wings 4 do not fall out. ), And then center the housing (2) while tightening the adjustment screw (17) to the screw hole (16).

The state after the assembly is as shown in Figure 3 from the cover 5 side. Since the inner circumferential surface of the housing 2, which is always in contact with the outer end of the wing 4 for sucking and discharging sludge, is protected by the rubber liner 7, the wear of the outer end of the wing 4 proceeds very slowly. The replacement cycle of (4) can be significantly increased.

If the wing 4 is not in the liner 7 during pumping, that is, when the pin guide tube 13 does not exist when passing through the inner end regions of the inlet port a and the outlet port b (dotted blades), the wing ( 4) the centrifugal force will cause the ring 12 to protrude in the centrifugal direction until it touches the inner circumferential surface of the groove 10, but the pin guide tube 13 whose inner circumferential surface is located just outside the orbit of the pin 11 may be used. It doesn't work because it prevents it.

Since the liner 7 is not attached to the inner end of the suction port a, the space is large. Thus, as a large space is secured to the inner end of the inlet port (a), even if solids such as metal fragments, broken glass fragments, and rubble are mixed in the sludge sucked therein, the blades (4) are collected together to the discharge port (b). It is easier to drive toward. Thus, the suction overload on the tip portion 7c of the liner 7 is alleviated, and the outer end of the wing 4 passing therethrough is also safe from the hazards of being solid. The discharge port b in which the liner 7 is not installed tends to discharge the introduced solids.

When the sludge sucked by the blade 4 moves toward the discharge port b, part of the sludge and part of the remaining excess sludge are discharged to the filling groove 7b, and eventually the closed space 8 is discharged. Is filled with sludge. The sludge filled in the enclosed space 8 is an equal pressure holding means for maintaining the pressure in the housing 2 and the pressure in the enclosed space 8 at equal pressure, so that the main body 1, the housing 2, and the housing 2 and The sealing function of the O-ring 22 interposed between the covers 5 is complemented.

When the sludge mixed with solids is sucked and discharged for a long period of time, especially when it is found that the abrasion wear is such that the pumping efficiency of the liner 7 attached to the suction-discharge section at the inner end of the suction port a decreases in the pumping efficiency. By selectively loosening and tightening the adjusting screw 18 of each part, the tip portion 7c is approached to the rotor 3 to close the gap with the blade 4 to suppress the pumping efficiency from being lowered.

The present invention as described above is very economical by attaching a liner to the inner peripheral surface of the housing in which the outer end of the wing is always in contact to induce ductile friction, thereby significantly increasing the replacement cycle of the wing due to early wear of the outer end. Of course, the wear of the housing can be reduced.

In addition, since a liner is not attached to the inner ends of the suction port and the discharge port to secure a relatively large internal space, it is possible to provide a high performance vane pump that can efficiently suck and discharge sludge mixed with solids.

In addition, even if the tip of the liner is abrasion due to the solid mixture of the sludge, the pumping efficiency is reduced, the pumping function can be compensated by simply moving the center of the housing with the adjustment screw from the outside to the rotor to approach the rotor.

Claims (1)

Into the housing 2 of the motor-embedded main body 1, a rotor 3 having a plurality of blades 4 inserted therein is inserted in a blade groove 9 formed radially, and the front of the housing 2 is covered with a cover 5. In the vane pump to be protected, the housing 2 having the inlet port a and the outlet port b is separated from the main body 1, and the inlet port a and the outlet port b are separated from the inner circumferential surface of the housing 2. A rubber liner 7 is attached to a portion other than the inner end, and a circular groove 10 corresponding to half of the thickness is formed concentrically in the center of the rotor 3, and the latter half of the wing 4 is formed. In the cover side to the depth of the groove (10) to form a pin 11 in the axial direction parallel to the inner end of the place, the inner surface of the cover (5) housing (2) and concentric wings ( The pumping trajectory maintenance pin guide tube 13 of 4) is formed, and the pumping trajectory maintenance vent 14 of the blade 4 is formed at the inner center thereof, and the housing 2 is formed. Characterized in that the housing screw for adjusting the movement of the center of the housing is fastened to a screw hole 16 drilled in an orthogonal direction in the middle of the bolt 6 for fastening and assembling the main body 1 and the cover 5 in between. Vane pump.