KR101345091B1 - Vertical pump - Google Patents

Abstract

The present invention relates to a vertical pump in which a cylindrical impeller having multiple spiral holes formed radially is installed at the lower inlet of an L-shaped casing. The vertical pump of the present invention for realizing the same comprises: a casing part comprising a suction casing fixed to be vertically inserted into a tank, a connection casing of which the inlet is connected to the upper side of the suction casing, and a discharge casing connected to the outlet of the connection casing, wherein the suction casing and the discharge casing are perpendicular to each other; a driving part comprising a driving motor fixed to the connection casing, a shaft connection member installed inside the suction casing and coupled to the rotary shaft of the driving motor, and a metal bearing installed inside the suction casing and supporting the shaft connection member, wherein the metal bearing comprises a driving part consisting of an upper and a lower bearing which are respectively installed at the insertion hole of the connection casing and the lower end portion of the suction casing; and a spiral hole impeller comprising a cylindrical impeller main body, and the spiral holes which are formed inside the impeller main body and are arranged at equal distances, wherein the impeller main body has the rotary shaft of which the upper side is coupled to the lower end portion of the shaft connection member and the lower side is supported by the lower bearing.

Description

Vertical Pumps {Vertical Pump}

The present invention relates to a axial pump, and more particularly, to a axial pump having a cylindrical impeller in which a plurality of spiral holes are formed radially is provided at the lower inlet of the '-' shaped casing.

The pump is a machine for pumping fluid through the rotation of the impeller applied with the rotational force from the driver, and can be roughly divided into a vertical pump and a horizontal pump according to the rotation axis direction.

In the vertical pump, the soil casing and the inflow casing are perpendicular to each other, and an impeller is built in the lower part of the inflow casing. A driving motor is provided on the extension line of the inflow casing, so that the installation area is more concise than the horizontal shaft pump. It can be easily installed in a narrow place. In addition, since the axis of rotation of the driver and the axis of rotation of the impeller are on the same line, it is easy to extend the axis of rotation, and the reduction in efficiency of the pump due to the extension of the axis of rotation can be minimized.

When a high head pressure is required, that is, when the height of the tank or the reservoir is high, cavitation may be generated at the inlet side, and the vertical pump is provided with an impeller at the lower end of the extended rotating shaft to generate such bubbles. There is an advantage that can be prevented.

Various types of impellers are employed in the pump, and the higher the viscosity of the fluid to be pumped or the higher the pressure is required, the more it is necessary for the fluid to have a large kinetic energy for smooth pumping. Therefore, the impeller passage path of the fluid needs to be provided long so that a large kinetic energy is transmitted to the fluid through the impeller.

As a prior art of a vertical pump having an impeller having a long passage path as described above, Korean Utility Model Model No. 20-0291797 (Registration Date: 2002.09.30.) Is disclosed, and FIG. 1 is a schematic view showing the prior art. to be.

As shown in FIG. 1, the prior art has a spiral multi-groove 2 formed in a cylindrical impeller 1 having a predetermined length, and a large kinetic energy is generated while a fluid flows through the spiral multi-groove 2. Received is characterized in that it is to be sent to the top. However, in the prior art, due to the pressure difference between the upper and lower sides of the impeller 1 and the friction between the casing 3 and the fluid material, the fluid material is transferred through the space between the casing and the impeller 1 or the outer space of the spiral multi-groove 2. There is a problem of backflow, which has a disadvantage in that the efficiency of the pump is lowered.

KR 20-0291797 Y1 2002.09.30.

The present invention has been made to solve the problems of the prior art, the problem to be solved in the present invention is to provide a pump for preventing the back flow of fluid in the boundary space of the casing and the impeller.

In addition, the problem to be solved by the present invention is to provide a pump that is stable in the rotation and pumping of the impeller.

In addition, the problem to be solved in the present invention is to provide an easy installation pump according to the site situation.

The vertical pump of the present invention for solving the above problems, the suction casing is inserted into the tank tank fixed vertically, the inlet is made of a connection casing connected to the upper portion of the suction casing and the discharge casing connected to the outlet of the connection casing. The casing portion provided with the suction casing and the discharge casing are formed to be perpendicular to each other; A drive motor fixed to the connection casing, a shaft coupling member provided in the suction casing and coupled to the rotation shaft of the drive motor, and a metal bearing supporting the rotation shaft rotated by the drive motor, wherein the metal bearing is the A driving part comprising an upper bore and a lower bearing respectively provided at an insertion hole of a connection casing and a lower end of the suction casing; And a plurality of spiral holes formed in the cylindrical impeller body and the impeller body and forming equal intervals. The upper part of the rotating shaft of the impeller body is coupled to the lower end of the shaft fitting member, and the lower part of the rotating shaft is connected to the lower bearing. It is characterized by consisting of; spiral hole impeller supported by.

In addition, the axial pump of the present invention is characterized in that a plurality of spiral projections are formed on the circumferential surface of the impeller body at equal intervals.

In addition, the axial pump of the present invention is further provided with a sealing member for preventing the leakage of the fluid on the rear surface of the upper bearing, characterized in that the assembly flange is further provided at both ends of the suction casing and the lower end of the discharge casing. do.

According to the present invention, since the backflow of the fluid is prevented through the spiral hole and the spiral protrusion of the spiral hole impeller, the efficiency of the pump can be improved.

In addition, according to the present invention, since the rotation of the impeller and the pumping of the pump are made stable through the metal bearing and the sealing member, the operation reliability can be improved.

In addition, according to the present invention, it is possible to install the vertical pump according to the tank tank height through the shaft fitting member and the assembly flange can improve the workability.

1 is a schematic view showing a vertical pump according to the prior art.
Figure 2 is a front view showing a particle pump according to the present invention.
Figure 3 is an exploded view showing a particle pump according to the present invention.
Figure 4 is a perspective view showing a spiral hole impeller of the granular pump according to the present invention.
Figure 5 is a cross-sectional view showing another embodiment of the spiral hole impeller according to the present invention.

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

Figure 2 is a front view showing a vertical pump according to the present invention, Figure 3 is an exploded view showing a vertical pump according to the present invention, Figure 4 is a perspective view showing a spiral hole impeller of the vertical pump according to the present invention. 2 to 4, the present invention provides a casing part 10 formed with a letter 'a', a driving part 20 provided in the suction casing 11 and the connection casing 13 of the casing part 10 and It consists of a spiral hole impeller 30 provided in the lower portion of the suction casing (11).

The present invention provides a boundary space between the suction casing 11 and the spiral hole impeller 30 when the fluid is pumped through the spiral hole 33 and the spiral protrusion 35 formed on the inner and outer circumferential surfaces of the spiral hole impeller 30, respectively. It is characterized in that the backflow that can occur in is prevented.

The casing part 10 serves to supply the fluid stored in the tank to the upper part and then supply it to the outside through a pipe connected to the discharge port 15a.

To this end, the casing portion 10 is a suction casing 11 is inserted into the tank tank vertically installed, the connection casing 13, the inlet 13a is connected to the upper portion of the suction casing 11 and the connection The discharge casing 15 is connected to the discharge port 13b of the casing 13, and the suction casing 11 and the discharge casing 15 are provided at right angles to each other.

The suction casing 11, the connection casing 13 and the discharge casing 15 may be provided integrally or assembling with each other, and when assembled, the assembling flanges 17 are formed at each end. In particular, since the suction casing 11 is different in height of the tank tank to be installed, it is preferable that the suction casing 11 and the connection casing 13 is provided in a prefabricated manner for ease of construction.

Therefore, an assembly flange 17 is provided at the upper end of the suction casing 11, and an assembly flange 17 is also provided at the lower end of the suction casing 11. At the lower end, a support end 14 having an increased cross-sectional area toward the lower end is provided with the assembly flange ( 17) to be detachably fixed. The support end 14 is provided in contact with or spaced apart from the tank bottom surface in the state in which a plurality of holes for the fluid inlet is formed on the circumferential surface.

In addition, a separate filtration means may be further provided inside the support end 14 to prevent the inflow of solids of a predetermined size or more into the fluid, and in particular, when a foreign material is introduced into the steel, it may cause a pump failure. Magnetic member for may be further provided.

The connecting casing 13 serves to redirect the fluid flowing vertically through the suction casing 11, and a curved portion 13c having a curved shape is formed on the outer surface to smoothly change the direction of the fluid. . An insertion hole 13d is formed in the curved portion 13c so that the rotating shaft of the driving unit 20 to be described later is penetrated and designed to have a material and a thickness having strength and rigidity that can support the impact force according to the change of the direction of the fluid. do.

In addition, in the case of the present invention, in order to prepare for the continuous vibration caused by the change of the direction of the fluid, it is preferable that the loosening prevention member such as a washer is provided in the screwing portion of each component to prevent loosening by vibration.

The driving unit 20 serves to rotate the spiral hole impeller 30 provided in the lower portion of the tank, for this purpose is provided in the drive motor 21, the suction casing 11 provided in the curved portion 13c. It consists of a shaft joint member 23 coupled to the rotation shaft of the drive motor 21 and a metal bearing 25 supporting the rotation shaft of the drive motor 21 and the spiral hole impeller 30.

At the end of the rotation shaft of the drive motor 21 and the spiral hole impeller 30, the shaft coupling member 23 having a length corresponding to the height of the tank tank to be installed is connected and fixed through the coupling 23a, etc. In order to maintain stability of the metal bearing 25 due to the torsional deformation according to this, it should be provided to have a material and diameter with sufficient strength and rigidity.

The metal bearing 25 is composed of an upper bearing 26 and a lower bearing 27, each of which is an insertion hole 13d of the connection casing 13 and a lower end or support end 14 of the suction casing 11. Support the rotating shaft of the drive motor 21 and the spiral hole impeller 30 in the state provided at the top, and serves to allow the spiral hole impeller 30 to be described later to rotate stably.

That is, when the shaft fitting member 23 is long or a solid foreign material is introduced into the spiral hole impeller 30, the spiral hole impeller 30 and the suction casing 11 may be in contact with each other, and wear may occur. As the upper bearing 26 and the lower bearing 27 support both ends of the rotating shaft, such abrasion problems can be prevented. The upper bearing 26 is preferably provided with a sealing member 28 on the rear surface to prevent the leakage of fluid due to the characteristics provided in the insertion hole (13d) of the connection casing (13).

In general, when the pressure difference is large before and after the flow direction of the fluid, backflow occurs in the boundary space between the pipe and the impeller. In particular, in the case of a high-pump pump, the backflow is easily generated by the large pressure difference before and after the impeller. This can be degraded.

The spiral hole impeller 30 is an impeller for pumping fluid to the upper side while minimizing the reverse flow as described above. For this purpose, the cylindrical impeller main body 31 and the impeller main body 31 are formed at equal intervals. It is formed of a plurality of spiral holes 33 and a plurality of spiral protrusions 35 formed on the circumferential surface of the impeller body 31 and forming an equal interval.

Unlike the pipe in which the inner wall of the spiral hole 33 is stopped, the inflow of the fluid flows upward by the spiral inner wall to prevent backflow.

Since the spiral hole impeller 30 continuously generates shock and vibration due to solid matter mixed in the fluid, it is preferable that the spiral hole impeller 30 is integrally manufactured by casting to enhance impact resistance and shock resistance.

The impeller body 31 and the spiral hole 33 is sized according to the required head or flow rate, if a high flow rate is required, the impeller body 31 and the spiral hole 33 is made to be wider cross-sectional area, If the high head is required to be manufactured to increase the length, both cases are provided with a high output drive motor 21 of the corresponding specifications.

In addition, the lower end of the spiral hole 33 may be further provided with a guide feather 34 as shown in Figure 5 so that fluid is easily introduced into the spiral hole 33 when the impeller body 31 is rotated. .

In addition, the impeller main body 31 has a predetermined gap between both members so that the impeller body 31 does not come into contact with the suction casing 11 when rotating, and the reverse flow of the fluid may occur through the gap, so that the spiral protrusion 35 Backwards are prevented by allowing fluid to be forced upwards, even between voids.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, 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.

10: casing part
11: suction casing 13: connecting casing
15: discharge casing 17: assembly flange
20:
21: drive motor 23: shaft coupling member
25: metal bearing 26: upper bearing
27: lower bearing 28: sealing member
30: spiral hole impeller
31 Impeller Body 33 Spiral Hall
35: spiral protrusion

Claims (4)

In the vertical pump provided in the tank tank,
The suction casing 11 and the inlet port 11a which are inserted and fixed perpendicularly to the tank tank are connected to the connection casing 13 connected to the upper portion of the suction casing 11 and the discharge port 11b of the connection casing 13. Comprising a discharge casing 15, the suction casing (11) and the discharge casing (15) is provided with a casing portion 10 to be formed at right angles to each other;
A drive motor 21 fixed to the connection casing 13, a shaft coupling member 23 provided in the suction casing 11, and coupled to a rotating shaft of the drive motor 21, and the drive motor 21. It consists of a metal bearing 25 for supporting the rotating shaft rotated by, the metal bearing 25 is an upper bearing provided in the lower end of the insertion hole 13d and the suction casing 11 of the connection casing 13, respectively A drive unit 20 including a 26 and a lower bearing 27; And
A cylindrical impeller body 31 and a plurality of spiral holes 33 formed in the impeller body 31 and formed at equal intervals, and the upper part of the rotating shaft of the impeller body 31 is the shaft joint member ( A spiral hole impeller 30 coupled to a lower end of the 23 and supported by the lower bearing 27;
A vertical pump, characterized in that consisting of.
The method of claim 1,
On the circumferential surface of the impeller body 31,
A axial pump, characterized in that the plurality of spiral projections (35) formed at equal intervals to each other is further provided.
The method of claim 1,
On the back of the upper bearing 26,
A vertical pump, characterized in that the sealing member 28 is further provided to prevent leakage of fluid.
The method of claim 1,
Both sides of the suction casing (11) and the lower end of the discharge casing (15) assembly pump (17), characterized in that further provided.

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