KR101346001B1 - High pressure fluid pump equipped with inducer - Google Patents

Abstract

A high pressure fluid centrifugal pump with an improved structure has a space (11) for a shaft, in which a rotor shaft (21) is mounted and an impeller space (15) in which a rotor impeller (25) is mounted and comprises a rotor housing (10) to which a rotor unit (20) is fixed to be rotated; the rotor unit (20) with the rotor shaft (21) which is fixed to the rotor housing (10) by a first bearing and the rotor impeller (25) mounted at the impeller space (15) to be rotated; an input/output housing (30) which comprises a fluid inflow pipe (31) and a fluid outlet pipe (32), is coupled to the rotor housing (10) and has a cylindrical intermediate space (35) with a first diameter (D1) connected with a hollow part (31a) of the fluid inflow pipe (31) at a central axis; an output tube (40) which has a tube output unit (41) in which an input gap (GAP) is mounted in the intermediate space (35) and a tube capture unit (45) for capturing a fluid by being formed in a radial direction through the impeller space (15), and is fixed at the input/output housing (30). [Reference numerals] (AA) Bearing;(BB) Sleeve

Description

High Pressure Fluid Pump Equipped With Inducer

The present invention relates to a structurally improved high pressure centrifugal fluid pump.

The effective suction head (hereinafter referred to as NPSH) is a measure of whether the pump can be safely operated without cavitation (CAVITATION) when operating the pump. NPSHrequired, hereinafter referred to as NPSHr).

NPSHa is a value determined irrespective of the pump itself by the pump installation conditions and piping system, such as the distance between the water surface and the pump, the suction pipe diameter and suction pipe length, and the temperature of the transfer liquid. This can be improved by increasing the pressure, lowering the fluid temperature, and modifying the pipe. NPSHr is a unique value of the pump.

Under normal conditions, when all other conditions affecting the performance of the pump are taken out of the way, the standard atmospheric pressure (1.0332 kg / cm2) corresponds to 10.332 mAq of vacuum water and a height of 10.332 m. NPSHr is based on 10.332m, and the depth that the pump can transfer water corresponds to the value of 10.332m-NPSHr. Therefore, the lower the NPSHr value, the better the pump that can transfer water deeper. can do.

There are a number of applications, such as patent applications 10-1998-0708166, 10-2000-0057725, as the prior art of the high pressure pump. This conventional high pressure fluid pump has a complicated configuration of the device and has difficulty in improving NPSHr.

An object of the present invention is to provide a high pressure centrifugal fluid pump having improved durability and high productivity while providing a discharge pressure of 100 BAR or more.

An inducer was introduced in the sleeve to improve the pump's suction capacity (improved NPSHR), resulting in a low flow, high lift pump.

The structure-improved high pressure centrifugal fluid pump of the present invention is a high pressure centrifugal fluid pump,

A rotor housing 10 having a shaft space 11 in which the rotor shaft 21 is embedded and an impeller space 15 in which the rotor impeller 25 is built, and in which the rotor part 20 is rotatably fixed;

A rotor part (20) comprising a rotor shaft (21) rotatably fixed to the rotor housing (10) with a first bearing and a rotor impeller (25) rotatably embedded in the impeller space (15);

The first diameter D1 is provided with a fluid input tube 31 and a fluid output tube 32, coupled to the rotor housing 10, and communicating with a hollow portion 31a of the fluid input tube 31 on a central axis. An input / output housing 30 in which a cylindrical intermediate space 35 having a width is formed;

A tube output part 41 is formed so as to form an input gap GAP in the intermediate space 35, and a tube trapping part 45 is formed radially across the impeller space 15 to trap fluid. And an output tube 40 fixed to the input / output housing 30.

According to the present invention, it is possible to provide a discharge pressure of 100 BAR or more, and to provide an improved high-pressure centrifugal fluid pump having excellent durability and high productivity.

According to the present invention, a low flow rate high lift pump is provided by introducing an inducer into the sleeve to improve the suction capacity of the pump (NPSHR improvement).

1 (a, b) is the overall configuration of the high-pressure centrifugal fluid pump of the structural improvement according to the first embodiment (fan type endurance plate) and the second embodiment (spiral type inducer plate) of the present invention.
2 (a, b) is a detailed view of the main portion of the structure-improved high-pressure centrifugal fluid pump according to the first embodiment (fan type endurance plate) and the second embodiment (spiral type inducer plate) of the present invention.
Figure 3 (a, b) is a detailed view of the sleeve of the structure improved high pressure centrifugal fluid pump according to the first embodiment of the present invention.
Figure 4 (a, b) is a detailed view of the sleeve of the structure improved high pressure centrifugal fluid pump according to a second embodiment of the present invention.

Hereinafter will be described a structure improved high pressure centrifugal fluid pump according to an embodiment of the present invention. 1 (a, b) is the overall configuration of the high-pressure centrifugal fluid pump of the structural improvement according to the first embodiment (fan type endurance plate) and the second embodiment (spiral type inducer plate) of the present invention, 2 (a, b) is a detailed view of the main parts of the structure-improved high-pressure centrifugal fluid pump according to the first embodiment (fan type inductor plate) and the second embodiment (spiral type inducer plate) of the present invention. Figure 3 (a, b) is a detailed view of the sleeve of the structure-improved high-pressure centrifugal fluid pump according to the first embodiment of the present invention, Figure 4 (a, b) is a structure improvement according to a second embodiment of the present invention Of the high pressure centrifugal fluid pump shown.

As shown in Figures 1 to 4, the structure-improved high-pressure centrifugal fluid pump according to an embodiment of the present invention, the rotor housing 10, the rotor portion 20, the input / output housing 30 and the output tube ( 40).

As shown in FIGS. 1 to 4, the rotor housing 10 forms a shaft space 11 in which the rotor shaft 21 is embedded, and an impeller space 15 in which the rotor impeller 25 is embedded. The part 20 is rotatably fixed.

1 to 4, the rotor part 20 is rotatably embedded in the impeller space 15 and the rotor shaft 21 which is rotatably fixed to the rotor housing 10 with a first bearing. It consists of the rotor impeller 25. The input / output housing 30 includes a fluid input tube 31 and a fluid output tube 32, is coupled to the rotor housing 10, and has a hollow portion 31a of the fluid input tube 31 at a central axis thereof. A cylindrical intermediate space 35 having a first diameter D1 communicating therewith is formed.

As shown in FIGS. 1 to 4, the output tube 40 has a tube output part 41 in which an input gap GAP is formed in the intermediate space 35, and a radius over the impeller space 15. It is formed in the tube trapping portion 45 is formed in the direction to capture the fluid, it is fixed to the input and output housing 30.

As shown in Figure 1 to 4, in the structure-improved high-pressure centrifugal fluid pump according to an embodiment of the present invention, the rotor impeller 25 is coupled to rotate integrally, the fluid acceleration passage 121 is It is configured to further include; fluid acceleration plate 120 formed to extend in a plurality in the radial direction. In the fluid acceleration plate 120, the fluid flowing from the input gap GAP of the intermediate space 35 flows into the inlet 121a of the fluid acceleration passage 121, and the fluid acceleration plate 120 is the rotor. By rotating integrally with the impeller 25, the fluid is accelerated and discharged to the outlet 121b of the fluid acceleration passage 121, and the discharged fluid flows into the capture hole 45a formed at the end of the tube capture portion 45. do.

As shown in Figure 1 to 4, in the structure improved high-pressure centrifugal fluid pump according to an embodiment of the present invention, further comprising a hollow sleeve 130 located in the intermediate space 35, hollow sleeve The other side of the 130 is integrally coupled to one side of the fluid acceleration plate 120, the tube output portion 41 is preferably interpolated (상기) of the hollow sleeve 130.

As shown in Figures 1a to 3 (a, b), in the structure-improved high-pressure centrifugal fluid pump according to an embodiment of the present invention, a fan type protruding radially on the inner peripheral surface of the hollow sleeve 130 At least two inducer plates 135 are provided, and the inducer plates 135 are formed to be spaced apart from each other, so that a gap groove 135a is formed between the inducer plates 135. The fan type is a concept that includes the shape of a plate or a normal fan having parallel planes.

As shown in Figures 1 to 4, in the structure-improved high-pressure centrifugal fluid pump according to an embodiment of the present invention, the inducer plate 135 is preferably composed of two to eight. It is preferable that the radial axis (axis R) is perpendicular to the axial direction (axis Z), and the inducer plate 135 is twisted without being horizontal with the radial axis (axis R) of the hollow sleeve 130. It is preferable that the radial axis (axis R) of the inducer plate 135 and the hollow sleeve 130 is 1 to 45 degrees.

The following describes the suction and discharge pressure measurement results according to the flow rate when there is no inducer and when there is an inducer.

When there is no inducer, the suction pressure is 0.6BAR at a flow rate of 12.5m ^{3, and} when the inducer of the present invention is mounted, the suction pressure (relative pressure) increases to 0.7 BAR.

< Inducer  When no test results>

380v 30kw (40Hp) rpm 4858 Rated Current 65A

Inducer Removal Results

flux Min. flow 0m ³ 5 m ³ 7.5m ³ 10 m ³ 12.5m ³ 15 m ³ 20m ³ Suction pressure bar 0.75 0.7 0.6 0.6 0.6 0.6 0.5 0.4 Discharge pressure bar 36 46 45 43 42 41 40 power A 41 40 43 48 55 60 60 70

< Inducer  When there is a test result>

380v 30kw (40Hp) rpm 4858 Rated Current 65A

Inducer type: Fan type 4ea

Outer diameter 69mm, inner diameter 45mm width 20mm thickness 2mm 8 degrees Mech. Seal spring added (inner pressure 4kgf / cm2)

flux Min. flow 0m ³ 5 m ³ 7.5m ³ 10 m ³ 12.5m ³ 15 m ³ Suction pressure bar 0.9 0.95 0.7 0.7 0.7 0.7 0.7 Discharge pressure bar 36 47 47 46 45 44 40 power A 41 40 41 46 49.8 55.3 61.2 75A

As shown in Figure 1b, Figure 4 (a, b), in the present invention, the spiral type inducer plate 135 of the spiral (spiral type) extending in the circumferential direction on the inner circumferential surface of the hollow sleeve 130 is At least two are preferably provided. The spiral type inducer plate 135 may be provided along the inner circumferential surface of the hollow sleeve 130.

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, &Lt; RTI ID = 0.0 &gt; and / or &lt; / RTI &gt;

It is to be understood that the appended claims are intended to supplement the understanding of the invention and should not be construed as limiting the scope of the appended claims.

10 rotor housing 11 space for shaft
15 impeller space 20 rotor portion
21 rotor shaft 25 rotor impeller
30 input and output housing 31 fluid input tube
31a: hollow part 32: fluid output tube
35: medium space 40: output tube
41 tube output portion 45 tube capture portion
45a: capture hole 120: fluid acceleration plate
121: fluid acceleration passage 121a: fluid acceleration passage inlet
121b: fluid acceleration channel exit 130: hollow sleeve
135: inducer plate 135a: niche groove

Claims (9)

In the high pressure centrifugal fluid pump,
A rotor housing 10 having a shaft space 11 in which the rotor shaft 21 is embedded and an impeller space 15 in which the rotor impeller 25 is built, and in which the rotor part 20 is rotatably fixed;
A rotor part (20) comprising a rotor shaft (21) rotatably fixed to the rotor housing (10) with a first bearing and a rotor impeller (25) rotatably embedded in the impeller space (15);
The first diameter D1 is provided with a fluid input tube 31 and a fluid output tube 32, coupled to the rotor housing 10, and communicating with a hollow portion 31a of the fluid input tube 31 on a central axis. An input / output housing 30 in which a cylindrical intermediate space 35 having a width is formed;
A tube output part 41 is formed so as to form an input gap GAP in the intermediate space 35, and a tube trapping part 45 is formed radially across the impeller space 15 to trap fluid. And an output tube (40) fixed to the input / output housing (30). The method of claim 1,
And a fluid acceleration plate 120 which is integrally coupled with the rotor impeller 25 and rotates, and a plurality of fluid acceleration passages 121 extend in a radial direction.
In the fluid acceleration plate 120, the fluid flowing from the input gap (GAP) of the intermediate space 35 is introduced into the inlet (121a) of the fluid acceleration passage 121,
As the fluid acceleration plate 120 rotates integrally with the rotor impeller 25, the fluid is accelerated and discharged to the outlet 121b of the fluid acceleration passage 121, and the discharged fluid is caught in the tube capping part 45. High-pressure centrifugal fluid pump having a structural improvement, characterized in that flow into the capture hole (45a) formed at the end. 3. The method of claim 2,
Further comprising a hollow sleeve 130 located in the intermediate space 35,
The other side of the hollow sleeve 130 is integrally coupled to one side of the fluid acceleration plate 120,
The tube output part 41 is an improved high-pressure centrifugal fluid pump, characterized in that the interpolated (內 揷) of the hollow sleeve (130). The method of claim 3,
At least two fan type inducer plates 135 protruding in a radial direction are provided on an inner circumferential surface of the hollow sleeve 130,
The inducer plate (135) is formed spaced apart from each other is a structure improved high-pressure centrifugal fluid pump, characterized in that the gap groove (135a) is formed between the inducer plate (135). 5. The method of claim 4,
The inducer plate 135 is a high-pressure centrifugal fluid pump having a structural improvement, characterized in that consisting of two to eight. 5. The method of claim 4,
The radial axis (axis R) is perpendicular to the axial direction (axis Z),
The inducer plate 135 is structured and improved high-pressure centrifugal fluid pump, characterized in that the hollow shaft is not horizontal to the axis (axial R) of the sleeve (130). The method according to claim 6,
Structural improved high-pressure centrifugal fluid pump, characterized in that the induction plate 135 and the radial axis (axis R) of the hollow sleeve 130 is 1 ~ 45 degrees. The method of claim 3,
High pressure centrifugal fluid pump having a structural improvement, characterized in that the inner circumferential surface of the hollow sleeve 130 is provided with at least two spiral type inducer plate (135) extending in the circumferential direction. 9. The method of claim 8,
The spiral type inducer plate 135 is a structural high pressure centrifugal fluid pump, characterized in that provided along the inner circumferential surface of the hollow sleeve (130).

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