KR102145566B1 - Positive displacement pump for recirculating leaking fluids and increasing watertight effect - Google Patents

Abstract

The present invention relates to a rotary positive displacement pump for recirculating a leaked fluid and increasing a watertight effect, which pressurizes a bearing toward a rotor so as to pressure a side plate to be in close contact with the rotor, and resupplies a fluid leaked between a rotary shaft of the rotor and a shaft hole by returning the leaked fluid in a suction-side direction by using a discharge hole formed in the side plate. The rotary positive displacement pump includes: a pressure adjusting member for pressurizing, toward the rotor, the bearing for supporting the rotary shaft so that the side plate being in close contact with the bearing makes close contact with the rotor; a discharge induction groove which has a coupling helical part to which the pressure regulating member is helically coupled, and is formed outside of the shaft hole into which the bearing is fitted; a discharge groove for discharging the fluid introduced into the discharge induction groove; a pump case having a connection passage for connecting the discharge induction groove to the discharge groove for discharging the leaked fluid; the side plate which is installed inside the pump case, has a coating layer for preventing leakage of a working fluid by contacting a side portion of the rotating rotor, and has a discharge hole formed in one side thereof; and the rotor which is installed inside the pump case to rotate and has a pressure part that is formed on a side of a body having a gear-shaped wing part to protrude and maintains airtightness as an O-ring.

Description

A rotary displacement pump for recirculating leaking fluids and increasing watertight effect.

The present invention relates to a rotary displacement pump, and more particularly, pressurizes a bearing supporting a rotary shaft toward the rotor to press the side plate in contact with the bearing to be in close contact with the rotor, and the fluid leaked between the rotary shaft of the rotor and the shaft hole is side The present invention relates to a rotary displacement pump to obtain recirculation of the leaked fluid and increase watertightness by returning the leaked fluid to the suction side and supplying it again using the discharge hole formed in the plate.

In general, a pump is a device that transfers fluid by starting by receiving power from a driving means such as a motor, and a non-economic pump in which energy is converted in an unsealed state, and energy is converted in a sealed state. This is distinguished by a positive displacement pump.

The non-discharge type pump is that the discharge pressure decreases as the discharge amount increases, and there are centrifugal pumps, sand flow pumps, axial flow pumps, etc. depending on the mechanism and structure. In addition, the positive displacement pump has a discharge amount that is approximately constant regardless of the load pressure, and includes a piston pump, a plunger pump, a gear pump, a screw pump, and a vane pump.

The positive displacement pump sucks liquid by vacuuming the inside of the cylinder with respect to the reciprocating linear motion of a piston, a plunger, or a bucket in a cylinder having a constant volume equipped with a suction valve and a delivery valve. It is a pump that supplies static pressure energy to a liquid by applying the required pressure to deliver water.

The rotary positive displacement pump rotates a special type of rotor in a casing, and a gear pump, a vane pump, and a screw pump are the main types. The gear pump moves the liquid between the teeth and the casing wall from the suction pipe to the discharge pipe as the gears rotate in engagement with each other in the container. Oil is usually used and the flow rate is small, but the pressure can be obtained up to 30 MPa. In the vane pump, the movable blades come in and out in the radial direction according to the rotation of the rotor, and the pressure is obtained up to about 40 MPa in the same way as a gear pump. Two to three screw rods are engaged and rotated to operate the pump. Mainly for oil, the pressure is within 20MPa.

In the conventional rotary positive displacement pump as described above, a lobular pump is used to extrude a liquid on the same principle as a gear pump. This can be seen as a reduced gear pump gear, and the structure is driven by a separate gear external to the counterpart because a set of rotors are meshed to prevent rotation of the counterpart.

The conventional rotary positive displacement pump can obtain a large lift coefficient and function as a pump even at low speeds, but it has a low flow rate and low efficiency when rotating at low speeds, and has disadvantages such as noise and wear of gears when rotating at high pressure and high speed. have.

In order to solve these problems, a rotary positive displacement pump, which is Korean Patent Registration No. 552597, has been proposed. A rotor part 200 that transfers fluid due to a change in volume due to a change in volume by rotation of the rotors 200a and 200b is installed inside the provided case 100, and a rotating shaft formed integrally with the rotors 200a and 200b In the sleeve 300 is fitted in the shaft hole of the wear plate 400, and in the chamber 110 formed in the case 100, a sealing means 500 installed on the rotating shaft of the rotor 200a, 200b prevents leakage. It is installed to prevent.

In the conventional rotary displacement pump having such a structure, due to processing errors and other errors of the side plate 400 installed in contact with the side plate 400 in contact with the rotors 200a, 200b, the rotor 200a ( There is a problem that a gap occurs between the 200b) and the pump case 100 and the side plates 200a and 200b are both made of metal, so that it is impossible to seal it, so there is a problem that leakage occurs frequently. In the rotary positive displacement pump, as shown in the accompanying drawings, the side where the fluid is supplied into the chamber 110 centering on an arbitrary centerline "O" is low pressure, and the side where the fluid is discharged is operated at high pressure, and the rotor When (200a) (200b) is compressed and transported at high pressure, water leaks along the rotating shaft, and the leaked fluid is delivered to the sealing means 500 at high pressure, which is damaged by the leaked high pressure fluid. As a problem occurs, there is a problem in that the efficiency of the pump is reduced or the lifespan is shortened.

Republic of Korea Patent Publication No. 2012-0082291 Korean Patent Registration No. 593208

The present invention conceived in consideration of these conventional problems enables adjustment of the pressing force that presses the bearing supporting the rotating shaft toward the rotor, and thus prevents leakage by making the side plate in contact with the bearing in close contact with the rotor by the above pressing force. In addition, a coating layer is formed on the surface of the side plate in contact with the rotating rotor to maintain airtightness, and a protrusion frame instead of an O-ring is integrally formed on the side of the rotor to prevent water leakage, and the rotation of the rotor. In this case, the life of the pump is increased by preventing damage to the sealing means from the fluid leaked by high pressure, and the efficiency of the pump is increased, and the leakage fluid recirculation and watertightness are increased by returning the leaked fluid to the supply direction and supplying it again. It is to provide a rotary positive displacement pump.

An object of the present invention as described above is a rotor part for transferring fluid is installed inside a pump case provided with a suction port and a discharge port, and a bearing is installed on the rotating shaft of the rotor, and a side plate provided with a shaft hole is fitted to the rotating shaft on which the bearing is installed. A rotary positive displacement pump, comprising: a pressure regulating member for pressing a bearing supporting a rotating shaft toward a rotor to adjust a side plate in contact with the bearing in close contact with the rotor; A discharge guiding groove to the outside of the shaft hole in which the pressure regulating member forms a coupling helical part and the bearing is fitted; A discharge groove for discharging the fluid introduced into the discharge induction groove; A pump case having a connection passage connecting the discharge induction groove and the discharge groove for discharging the leaked fluid; A side plate installed inside the pump case and provided with a coating layer to prevent leakage of working fluid by contacting a side portion of the rotating rotor and having a discharge hole formed at one side thereof; Recirculation of leaked fluid and increase watertightness, characterized in that it includes a rotor that is installed inside the pump case and rotates and has a compression portion protruding like an O-ring on the side of the body provided with a toothed wing portion. This is achieved by means of a rotating positive displacement pump that is designed to achieve the effect.

In the present invention, it is possible to adjust the pressing force that presses the bearing supporting the rotating shaft toward the rotor, and accordingly, the side plate in contact with the bearing is brought into close contact with the rotor by the aforementioned pressing force to prevent leakage, and the rotating rotor A coating layer is formed on the surface of the side plate in contact with the side plate to maintain airtightness, and a protrusion frame for O-ring is integrally formed on the side of the rotor to prevent leakage. It is a useful invention that prevents damage to the sealing means from the fluid, prolongs the life of the pump, increases the efficiency of the pump, and returns the leaked fluid to the supply direction to resupply it.

1A and 1B are an exploded perspective view and a combined cross-sectional view showing the structure of a general rotary displacement pump.
2 is an exemplary view showing a pressure state according to the structure of a general rotary displacement pump.
3 is a cross-sectional view showing the structure of a rotary displacement pump to which the technology of the present invention is applied.
Figure 4a is an exploded perspective view showing the structure of a pump case to which the technology of the present invention is applied.
Figure 4b is a front view showing the structure of the pump case, the technical gist of the present invention.
5 is a perspective view showing the structure of a rotor, which is a technical gist of the present invention.
6A is an exemplary view showing an installation state of a side plate provided with a discharge hole in a pump case.
6B is a cross-sectional view showing another embodiment of an outlet.
7 is a front view showing a structure for recirculating the leaked fluid between the pump case and the side plate.

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

3 is an exploded perspective view showing the structure of a rotary displacement pump to which the technology of the present invention is applied, and FIG. 4A is an exploded perspective view showing the structure of a pump case to which the technology of the present invention is applied, and FIG. 4B is a technical gist of the present invention. As a front view showing the structure of the pump case, the rotational displacement pump of the present invention has a pair of rotors 20 for transferring fluid in the pump case 10 provided with an inlet and a discharge port, and the rotor 20 The bearing 30 is installed on the rotation shaft 80 of the bearing 30, and the side plate 40 provided with a shaft hole is fitted to the rotation shaft 80 on which the bearing 30 is installed.

A discharge guide groove (16) and a discharge groove (13) for discharging the fluid flowing into the discharge guide groove (16) to the outside centering on the inner surface of the pump case (10), that is, the shaft hole (17) in which the bearing is installed And a connection passage 15 connecting the discharge induction groove 16 and the discharge groove 13 for discharging the leaked fluid.

A plurality of fixing holes 41 fixed to the pump case 10 are formed in the side plate 40 fixed in close contact with the pump case 10, and a shaft hole having the same center as the shaft hole 17 formed in the pump case 10 It is provided with a structure comprising a discharge hole 43 formed in a certain portion.

On the other hand, the side plate 40 is made of a metal material as shown in the accompanying drawings Fig. 6A, and the main plate 44 having the fixing hole 41 and the shaft hole 17 formed thereon, and the surface of the main plate 44 are silicone, rubber. , An elastic layer 45 such as ceramic is provided, and a discharge hole 43 is formed on one side thereof.

The discharge hole 43 may be formed to be vertically perpendicular, but as shown in the accompanying drawings, FIG. 6B, a fluid to be recirculated by forming an inclined surface in the discharge hole 43 according to the direction of the supplied fluid is supplied at low pressure. It can also be easily included in.

The discharge guide groove 16 is preferably formed on a concentric circle with the shaft hole 17, and the discharge guide groove 16 is concentric with the shaft hole 17 as shown in Figs. 4A to 4B. It is formed and can be used by being divided into first and second discharge induction grooves 16a and 16b.

As described above, when the discharge guide groove 16 is divided into a first discharge guide groove 16a and a second discharge guide groove 16b around the shaft hole, water leakage and shaft hole 17 near the shaft hole 17 This is because it is effective because it can collect and discharge water from the area far from ), and it can effectively respond even when the amount of leaked fluid is large.

Meanwhile, as shown in FIG. 4B of the accompanying drawings, the shaft hole 17 and the second discharge guide groove 16b formed on a concentric circle overlap each other to form a coupling groove 18 to meet each other. As described above, the reason for forming the coupling groove 18 where the second discharge guide grooves 16b overlap and meet each other is that a space is formed between the second discharge guide groove 16b and the second discharge guide groove 16b. This is to prevent the occurrence of non-functional parts. In addition, this is because there is an advantage of miniaturization by shortening the distance between axes.

In the pump of the above structure, the bearing 30 supporting the rotating shaft 80 is pressed toward the rotor 20 to prevent contact between the pump case 10 and the rotor 20 while holding the position of the rotor 20 The pump case 10 is provided with a coupling screw so that the pressure control member 50 for adjusting the side plate 40 to be in close contact with the rotor 20 can be installed.

The pressure regulating member 50 has two types, a cap shape in which the head 51 is hung outside the pump case 10, and a plate plate type that is screwed into the pump case 10.

The cap-shaped pressure control member 50 is integrally formed with a head 51 that can be rotated using a hand or a tool and a spiral portion formed on the outer circumferential surface thereof, and is combined with the spiral portion provided in the case. It is a structure consisting of a pressing portion 52 that is horizontally moved, and the plate-shaped structure is a structure consisting of a pressing portion 52a that is horizontally moved by being combined with a spiral portion provided in the case, and a tool is used at one end of the pressing portion 52a. The groove 53 is provided, and the shape of the groove 53 is a structure made of any one of straight, cross, square, and hexagonal.

On the other hand, as shown in the accompanying drawings, the rotor 20 is installed inside the pump case 10 and rotates, like an O-ring on the side of the body 22 provided with a toothed wing part 21 It is a structure made by protruding and forming a pressing portion 23 for maintaining airtightness.

The operation of the present invention having the structure as described above can be adjusted only at the time of repair and replacement of parts by disassembling the pressure control member 50 screwed into the pump case 10 during assembly production of the pump shown in FIG. Then, the distance between the side plate 40 and the rotor 20 is adjusted by using the pressure control member 50 coupled to the outside of the case of the pump when the pump is driven and before use after assembly of the pump.

When the head portion 51 is rotated by a tool or hand, the pressure regulating member 50 coupled to the outside is moved along the spiral portion formed in the pump case 10, and the bearing ( 30) is pressed toward the rotor 20.

When the bearing 30 is pushed into the pump case 10 by the pressurizing part 52, the space maintaining member 60 in contact with the bearing 30 is pushed and the side plate 40 is in close contact with the rotor 20. Pressurized to make it. When the interval adjustment is completed as described above, when the rotor 20 is rotated by transmitting a rotational force, the rotor 20 and the rotation shaft 80 rotate together.

At this time, friction occurs with the side of the rotor 20 and the side plate 40, and in the related art, the side plate is simply formed of a metal plate, so that the rotor 20 is worn, but in the present invention, the surface of the side plate 40 is elastic. A layer 42 is formed to prevent damage to the rotor 20 due to wear.

On the other hand, the rotor 20 is installed inside the pump case 10 and rotates, as shown in the accompanying drawings, FIG. 5, and is like an O-ring on the side of the body 22 provided with a toothed wing part 21. It is a structure made by protruding and forming a pressing portion 23 for maintaining airtightness.

The reason why the crimping portion 23 protrudes from the surface of the side is to adjust the distance between the side plate 40 and the side plate 40 to primarily prevent water leakage occurring between the side plate 40.

The ceramic coating layer may be applied to the entire side plate 40 or may be partially formed only on a plane to which the pressing portion 23 contacts. However, when water leakage occurs between the side plate 40 and the pump case 10, as shown in the accompanying drawings, the side where the fluid is supplied centered on an arbitrary centerline "O" is low pressure, and the fluid is caused by the compression force of the rotor. The discharge side is high pressure when the fluid compressed at the high pressure is transferred, and the fluid compressed at high pressure is leaked due to the gap between the rotating shaft 80 and the shaft hole 17 as shown in Figs. 6A to 6B of the accompanying drawings. Is done.

For example, when the side plate 40 is installed inside the pump case 10, the fluid leaked between the pump case 10 and the side plate 40 is filled while forming a high pressure, and the fluid is filled with the side plate ( 40) and the pressure control member 50 installed in the pump case 10 are pushed out with pressure.

Therefore, there is a problem in that the pressure control member 50 is damaged due to the high pressure of the leaked fluid due to the leaked high pressure fluid, and thus the efficiency of the pump is reduced or the lifespan is shortened.

However, in the present invention, when the side plate 40 is installed inside the pump case 10, the fluid leaked between the pump case 10 and the side plate 40 is filled while forming a high pressure, and the fluid is The pressure control member 50 installed in the side plate 40 and the pump case 10 is pushed out with pressure.

At this time, the leaked fluid flows into the discharge guide groove 16 formed concentrically with the shaft hole 17, and the introduced fluid moves toward a low pressure. Of course, it is preferable that a plurality of discharge guide grooves 16 are formed at regular intervals, such as the first discharge guide groove 16a and the second discharge guide groove 16b, rather than one formed.

The discharge guide groove 16 at the low pressure side is connected to the discharge groove 13 through a connection passage 15, so that the fluid is collected in the discharge groove 13, and the discharge hole of the side plate 40 by pressure As it is discharged through 43, it is mixed with the supplied fluid again and supplied again to the rotor.

At this time, an inclined surface is formed in the discharge hole 43 according to the direction of the fluid supplied to the discharge hole 43 as shown in Fig. 6B, so that the recirculated fluid can be easily included in the fluid supplied at low pressure. have.

In the present invention, it is possible to adjust the pressing force that presses the bearing supporting the rotating shaft toward the rotor, and accordingly, the side plate in contact with the bearing is brought into close contact with the rotor by the aforementioned pressing force to prevent leakage, and the rotating rotor A coating layer is formed on the surface of the side plate in contact with the side plate to maintain airtightness, and a protrusion frame for O-ring is integrally formed on the side of the rotor to prevent leakage. It is a useful invention that prevents damage to the sealing means from the fluid, prolongs the life of the pump, increases the efficiency of the pump, and returns the leaked fluid to the supply direction to resupply it.

10: pump case 13: discharge groove
15: connecting passage 16: discharge induction groove
16a: first discharge induction groove 16b: second discharge induction groove
17: shaft work 18: coupling groove
20: rotor 21: wing
22: body 23: compression portion
30: bearing 40: side plate
41: fixing hole 42: elastic layer
43: discharge hole 44: main plate
45: elastic layer 50: pressure control member
50a: pressure control member 51: head
52: pressing unit 52a: pressing unit
53: groove 60: gap maintaining member
80: rotating shaft 160: discharge guide groove

Claims (6)

In the pump case provided with a suction port and a discharge port, a rotor part for transporting fluid is installed, a bearing is installed on the rotation shaft of the rotor, and a side plate provided with a shaft hole is fitted to the rotation shaft on which the bearing is installed.
A pressure regulating member for pressing the bearing supporting the rotating shaft toward the rotor to adjust the side plate in contact with the bearing in close contact with the rotor;
A discharge guiding groove to the outside of the shaft hole in which the pressure regulating member forms a coupling helical part and the bearing is fitted; A discharge groove for discharging the fluid introduced into the discharge induction groove; A pump case having a connection passage connecting the discharge induction groove and the discharge groove for discharging the leaked fluid;
A side plate installed inside the pump case and provided with a coating layer to prevent leakage of working fluid by contacting a side portion of the rotating rotor and having a discharge hole formed at one side thereof;
Recirculation of leaked fluid and increase watertightness, characterized in that it includes a rotor installed inside the pump case to rotate and protruding a crimping portion that maintains airtightness like an O-ring on the side of the body provided with a toothed wing portion Rotary positive displacement pump designed to achieve the effect.
The method of claim 1,
The discharge induction groove is a rotary displacement pump to obtain the effect of recirculation and water tightness increase of the leaked fluid, characterized in that formed in the shaft hole and the concentric circle.
The method of claim 1,
The discharge guide groove is formed on the shaft hole and the concentric circle, and is formed of first and second discharge guide grooves, characterized in that the rotary displacement pump to obtain the effect of recirculation and watertight increase of the leaked fluid.
The method of claim 3,
The rotary displacement pump to obtain the effect of increasing the recirculation and watertightness of the leaked fluid, characterized in that the shaft hole and the second discharge guide groove formed on the concentric circle overlap each other to form a coupling groove.
The method of claim 1,
The pressure regulating member is a rotary displacement pump to obtain an effect of increasing watertightness and recirculation of the leaked fluid, characterized in that it consists of a cap-shaped head that is hung on the outside of the case and a pressurizing unit with a screw formed on the outer periphery integrally with the head. .
The method of claim 1,
The pressure regulating member is a rotary displacement pump to obtain the effect of increasing the recirculation and watertightness of the leaked fluid, characterized in that consisting only of a pressurizing portion formed with a screw on the outer circumferential surface so as to be screwed to the spiral portion inside the case.

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