KR102124541B1 - A rotary displacement pump for obtaining a watertightness increasing effect - Google Patents

Abstract

The present invention relates to a rotary positive displacement pump for obtaining a watertightness increasing effect and, more specifically, to a rotary positive displacement pump for obtaining a watertightness increasing effect, which presses a bearing for supporting a rotary shaft toward a rotor, thereby performing control such that a side plate being in contact with the bearing makes close contact with the rotor, and has a coating layer formed on the side plate for preventing leakage of a working fluid by making contact with a lateral portion of the rotor rotating, thereby reducing abrasion and increasing an airtight effect. The rotary positive displacement pump, in which the rotor for transferring a fluid is installed inside a pump case having an inlet port and an outlet port, the bearing is axially installed on the rotary shaft of the rotor, and the side plate having a shaft hole is fitted on the rotary shaft having the bearing installed thereon, comprises: a pressure control member for performing control so that the bearing for supporting the rotary shaft and the side plate make close contact with the rotor; the pump case having a coupling helical portion helically coupled to the pressure control member; the side plate having an elastic layer, and holding the position of the rotor while preventing contact between the case and the rotor by pressing, toward the rotor, the bearing for supporting the rotary shaft; and the rotor which is installed inside the pump case to rotate and has a pressure portion formed on the lateral surface of a body having a wing portion of a gear shape to protrude along an end of the wing portion.

Description

A rotary displacement pump for obtaining a watertightness increasing effect

The present invention relates to a rotary displacement type pump, and more specifically, by pressing a bearing supporting a rotating shaft toward the rotor, the side plate in contact with the bearing can be adjusted in close contact with the rotor and working fluid in contact with a side portion of the rotating rotor. It relates to a rotational displacement pump to form a coating layer on the side plate to prevent leakage of the water to increase the water tightness increase effect to reduce the wear and increase the sealing effect.

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-condensed pump that converts energy in an unsealed state, and converts energy in an enclosed state It is distinguished by this rising volumetric pump.

A cost-optimized pump is one in which the discharge pressure decreases as the discharge amount increases, and there are a centrifugal pump, a dead flow pump, an axial flow pump, etc. depending on the mechanism and structure. In addition, the positive displacement pump is substantially constant regardless of the load pressure, and there are a piston pump, a plunger pump, a gear pump, a screw pump, and a vane pump.

The positive displacement type pump pumps the cylinder into a vacuum for reciprocating linear motion such as a piston, plunger, or bucket by inhaling a liquid in a cylinder having a constant volume equipped with an intake valve and a discharge valve, and changing the volume. It is a pump that supplies and transmits constant pressure energy to the liquid by applying the required pressure.

The rotary displacement type pump rotates a special type of rotor in the casing, and mainly consists of a gear pump, vane pump, and screw pump. The gear pump rotates the gears engaged with each other in the container, and sends the liquid between the teeth and the casing wall from the suction pipe to the discharge pipe. Oil is common and flow rate is low, but pressure can be obtained up to 30MPa. In the vane pump, the movable blades come and go in the radial direction according to the rotation of the rotor, so that the pressure is obtained up to 40MPa in the same way as the gear pump, and the screw pump is The pump is operated by engaging and rotating two or three screw rods. Mainly for oil, the pressure is within 20 MPa.

In the conventional rotary displacement type pump as described above, there is a lobe pump for extruding a liquid on the same principle as a gear pump. This can be seen as reducing the gear pump's gear, and the structure can't rotate the opponent by engaging a set of rotors, so the opponent is driven by a separate gear outside.

The conventional rotary displacement type pump can obtain a large lift coefficient and exert its function as a pump even at low speeds, but it has a defect in that the flow rate is low and the efficiency decreases at low speed rotation, and noise and wear of gears occur at high speed and high speed rotation. have.

In order to solve the above problems, the Korean patent registration No. 552597, a rotary displacement type pump has been proposed, but the above-mentioned applicant's pre-registered rotary displacement type pump has an inlet and an outlet as shown in the accompanying drawings. Inside the provided case 100, a rotor unit 200 for transferring fluid due to a change in volume due to rotation of the rotors 200a and 200b is installed, and a rotating shaft integrally formed with the rotors 200a and 200b In the sleeve 300 is fitted to the shaft hole of the wear plate 400 is installed, the chamber 110 formed in the case 100, the sealing means 500 is accumulated on the rotation axis of the rotor (200a) (200b) leaks It is installed to prevent.

In a conventional rotary displacement type pump having such a structure, there is a problem that a clearance is generated between the rotors due to processing errors and other errors of a side plate installed in contact with a side plate contacting the rotor, and also rubber on the surface. Since the rotor rotates while the side plate made of metal and the side plate made of metal are in contact with each other, there is no problem even if there is a certain clearance between the rotating body (rotor) and the pump case during the transfer of viscous fluid, but it is not a problem. In case of normal transfer, especially during high-pressure transfer, the rotating body and the side plate must be in full contact to form a sealing structure, and sealing must also occur between the pump case and the side plate. Since it is impossible, there is a problem that leaks are frequently generated, and there is a problem that a rotor is worn out due to friction between the wear plate and the rotor, causing a leak.

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

The present invention has been devised in view of these conventional problems, and it is possible to control the pressing force for pressing the bearing supporting the rotating shaft toward the rotor, and thus the side plate in contact with the bearing is brought into close contact with the rotor by the pressing force to prevent leakage. The liquid is leaked by forming a coating layer on the surface of the side plate contacting the rotating rotor to maintain airtightness, and forming a stone ring on the side of the rotor to prevent bearings supporting the rotating shaft of the rotor from leaking ( It is to provide a rotational displacement pump to obtain a water tightness increase effect to prevent damage by water) and prevent a pressure drop from high pressure to low pressure due to edge loss.

The above object of the present invention is provided with a rotor for transferring fluid inside a pump case equipped with a suction port and a discharge port, a bearing is installed on a rotating shaft of the rotor, and a side plate provided with a shaft hole is installed on a rotating shaft where the bearing is installed. In a rotational displacement pump, a cap-shaped head hanging on the outside of the case to adjust the side plate holding the rotor in close contact with the rotor while preventing the contact between the pump case and the rotor by pressing the bearing supporting the rotating shaft toward the rotor A pressure regulating member consisting of a pressing part integrally formed with the head and the head and having a screw formed on its outer circumference; A pump case forming a coupling spiral part screw-coupled with the pressure regulating member; When the bearing is pressed toward the rotor using the pressure regulating member, the side plate is in close contact with the rotor by the pressing force and has an elastic layer on the surface; It is installed in the pump case and rotates, and a rotational displacement type pump for obtaining a water-tightening-increasing effect is characterized by comprising a rotor in which a crimping portion protrudes along an end portion of a wing portion on a side surface of a body provided with a gear-shaped wing portion. Is achieved by.

The pressure regulating member is achieved by a rotational displacement pump to obtain an effect of increasing water tightness, characterized in that it consists only of a pressurizing portion having a screw formed on its outer circumferential surface to be screwed to a spiral portion inside the case.

The present invention enables the adjustment of the pressing force for pressing the bearing supporting the rotating shaft toward the rotor, and thus the side plate in contact with the bearing is brought into close contact with the rotor by the pressing force to prevent leakage, and the rotating rotor A coating layer is formed on the surface of the side plate in contact with to maintain airtightness, and even if a leak occurs by forming an annular frame on the side of the rotor, bearings that support the rotating shaft of the rotor are damaged by leaking liquid (water). It prevents and prevents the pressure from being reduced from high pressure to low pressure due to edge loss, thereby improving the durability of the pump.

delete

1 and 2 are cross-sectional views showing the structure of a typical rotary displacement pump.
Figure 3 is a cross-sectional view showing the structure of a rotary displacement type pump to which the technology of the present invention is applied.
Figure 4 is a perspective view showing the structure of the rotor which is the subject matter of the present invention.
Figure 5 is a cross-sectional view showing the structure of the side plate that is the technical gist of the present invention.

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

Attached Figure 3 is a cross-sectional view showing the structure of a rotary volumetric pump to which the technology of the present invention is applied. Accordingly, the rotary volumetric pump of the present invention has a pair of fluids to be transferred inside the pump case 10 provided with an inlet and an outlet. The rotor 20 is installed, the bearing 30 is installed on the rotating shaft 80 of the rotor 20, and the side plate 40 provided with the shaft hole is installed on the rotating shaft 80 on which the bearing 30 is installed. Structure.

The side plate 40 is made of a metal material and has a structure in which an elastic layer 42 made of silicon, rubber, ceramic, or the like is provided on the main plate 41 on which the shaft hole is formed and on the surface of the main plate 41.

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

The pressure regulating member 50 is formed in two forms, and there are two types of a cap plate on which the head 51 is hung on the outside of the pump case 10 and a plate plate type screw-connected inside the pump case 10.

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

In the drawings, reference numeral 60 is a seal that is installed between the side plate 40 and the bearing 30 to prevent leakage.

On the other hand, as illustrated in FIG. 4, the rotor 20 is installed inside the pump case 10 to rotate, and the wing portion 21 is provided on the side surface of the body 22 provided with the gear portion 21 in the form of gears. The crimping portion 23 is formed to protrude along the end of the structure.

The side of the rotor 20 may be used by protruding a ring 25 connecting the crimping portion 23, between the rotor 20 and the side plate 40 or between the side plate 40 and the bearing ( 30) An additional seal can be installed between them.

The operation of the present invention having the structure as described above is the pressure adjustment member (50a) is screwed into the pump case 10 during assembly and production of the pump is disassembled and can be adjusted at the time of repair and replacement of the parts and after the assembly of the pump pump During driving and before use, the gap between the side plate 40 and the rotor 20 is adjusted using a pressure regulating member 50 coupled to the outside of the case of the pump.

The pressure regulating member 50 coupled to be exposed to the outside rotates the head part 51 with a tool or a hand, so that the pressing part 52 moves along the spiral part formed inside 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 pressing part 52, the spacer member 60 in contact with the bearing 30 is also pushed, and the side plate 40 is brought into close contact with the rotor 20. Pressure. When the gap adjustment is completed as described above, when the rotor 20 is rotated by transmitting rotational force, the rotor 20 and the rotating shaft 80 rotate together.

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

On the other hand, the rotor 20 is installed inside the pump case 10 and rotates as shown in FIG. 4 of the attached drawing, and the wing portion 21 is provided on the side of the body 22 provided with the gear portion 21 in the form of teeth. The pressing portion 23 is formed to protrude along the end of the structure having a ceramic coating layer on the side, and is further provided with an annular frame 25 having a concentric circle around an axis.

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

When a leak occurs between the side plate (40) and the rotor (20), secondary leakage is prevented by a stone ring (25) having a diameter smaller than that of the crimping portion (23). To prevent the pressure from dropping.

On the other hand, even if it is difficult to maintain the gap due to the wear of the crimping portion 23, the effect of maintaining the gap can also be obtained by the protrusion frame 25.

The protruding height of the crimping portion 23 should be formed to be the same or higher than that of the protruding frame 25. The reason is that the crimping portion 23 must first wear out due to friction.

The ceramic coating layer may be applied to the entire side plate 40 or partially formed only on a plane in which the crimping portion 23 and the rim 25 contact. The above-mentioned ceramic coating layer has a purpose to prevent abrasion of the crimping portion 23 and the rim ring 25, and also has a purpose of reducing the friction coefficient.

The present invention allows the adjustment of the pressing force pressing the bearing 30 supporting the rotating shaft 80 toward the rotor 20, and thus the side plate 40 in contact with the bearing 30 by the pressing force described above. To close the rotor 20 to prevent leakage, and to form a coating layer on the surface of the side plate 40 in contact with the rotating rotor 20 to maintain airtightness and stones on the side of the rotor 20 Even if water leakage occurs by forming a ring 25, the bearing 30 supporting the rotating shaft of the rotor 20 is prevented from being damaged by leaking liquid (water), thereby improving the durability of the pump. have.

10: pump case 20: rotor
21: wing 22: body
23: crimp 25: stone ring
30: bearing 40: side plate
41: main plate 42: elastic layer
50: pressure regulating member 50a: pressure regulating member
51: head 52: pressurization
52a: pressing part 53: groove
60: gap maintaining member 80: rotating shaft

Claims (4)

In the pump case provided with a suction port and a discharge port, a rotor part for transferring fluid is installed, a bearing is installed on a rotating shaft of the rotor, and a side plate with a shaft hole is fitted on the rotating shaft where the bearing is installed,
The cap-shaped head and the head are hung on the outside of the case to adjust the side plate holding the rotor in close contact with the rotor while pressing the bearing supporting the rotating shaft toward the rotor to prevent contact between the pump case and the rotor. A pressure regulating member made of a pressurized portion with a screw formed on an outer circumference of the furnace;
A pump case forming a coupling spiral part screw-coupled with the pressure regulating member;
When the bearing is pressed toward the rotor using the pressure regulating member, the side plate is in close contact with the rotor by the pressing force and has an elastic layer on the surface;
It is installed inside the pump case and rotates, the rotational displacement pump to obtain a water-tightness increase effect, characterized in that it comprises a rotor protruding along the end portion of the wing portion on the side of the body provided with a gear-shaped wing portion.
delete delete delete

Images