CN216770894U - Large-scale dredge pump impeller weighing type static balancing device - Google Patents

Abstract

The utility model discloses a large mud pump impeller weighing type static balancing device which comprises concentric rings, wherein a balancing disc is sleeved on the outer sides of the concentric rings, the balancing disc is formed by connecting an inner annular disc frame and a plurality of supports which are circumferentially distributed on the outer sides of the concentric rings, included angles between the adjacent supports are the same, a pressure sensor is arranged in each support, a jack and an equal-height cushion block are arranged between the adjacent supports, each support is a rectangular support, and the edge of each support is provided with a scale mark taking the circle center of the balancing disc as a starting point. The utility model adopts concentric rings, a balance disc, a pressure sensor and a jack to assemble the large-scale mud pump impeller weighing type static balance device, has simple structure, can adjust the position of the pressure sensor according to the diameter of the excircle of the impeller to be measured, realizes the adjustment of the measurement radius of the unbalanced moment, has good universality, is safe and convenient to operate and has reliable precision.

Description

Large-scale dredge pump impeller weighing type static balancing device

Technical Field

The utility model belongs to the technical field of electromechanical integration detection devices, and relates to a large-scale dredge pump impeller weighing type static balancing device.

Background

For a large rotor part such as a dredge pump impeller, the working speed is generally 250-350 rpm, the maximum diameter is close to 3 meters, the maximum weight is more than 10 tons, a main inertia shaft at the mass center of the impeller is not coincident with a rotation axis due to casting errors, uneven material structures, shape errors (particularly non-processing parts) of the part, asymmetrical local shapes and the like, unbalanced centrifugal force is generated during rotation, if the unbalanced centrifugal force is too large, the pump shaft, the bearing box and a pump body mounting base vibrate, the safe operation of the integral dredge pump is greatly influenced, and therefore static balance detection and correction are required to be performed when the impeller leaves a factory.

The traditional static balance process for rotor parts mainly adopts a steel ball type static balance method, and the method has the biggest defects of low precision, poor repeatability, high requirements on surface hardness, smoothness and the like of a balance ball and a mirror plate. And for large parts, because the steel ball and the mirror plate belong to a point contact mode, the dead weight of the overweight part causes the deformation of the bearing steel ball and the mirror plate, and the unbalance measurement and the balancing are directly influenced. The current more advanced static balance method is a stress rod balance method, but the method has high requirements on the material of the stress rod, each stress rod has to be independently tested for the elastic modulus, the processing period is long, the requirements on the arrangement position of a transformer are very strict, the tooling cost is high, the assembly is inconvenient, and the use is complicated.

The common static balancing process for the impeller of the dredge pump usually adopts a horizontal rotating shaft type, namely a dummy shaft which is concentric with the shaft end of the impeller and has the same diameter as the shaft end of the impeller is arranged at the suction end of the impeller, the impeller is erected and then placed on a bearing frame to rotate, the unbalanced part is positioned at the lowest point of the impeller after the impeller is static under the action of gravity, then a heavy object is added at the opposite position to balance the unbalanced weight until the stopping position of the impeller randomly appears, and the mass of the added heavy object is the unbalanced weight of the impeller at the moment. Such a method has the following problems: 1) the error is large under the influence of factors such as the flexible degree of rotation of the bearing frame, the friction force between the false shaft of the impeller and the bearing and the like; 2) when in operation, the impeller needs to be turned over, erected and lifted, is easy to topple and has poor safety; 3) the distance between the left bearing frame and the right bearing frame needs to be adjusted according to different impeller heights, and when the impeller is placed on the bearing frames, certain impact is inevitably generated on the bearings, and the bearing frames are damaged in the past; 4) a false shaft with the same diameter needs to be manufactured for each impeller with different shaft end diameters, so that the cost is high, and time and labor are wasted.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a large-scale mud pump impeller weighing type static balancing device, which solves the problems of larger measurement error and lower safety of the existing mud pump impeller static balancing device.

The technical scheme includes that the large mud pump impeller weighing type static balancing device comprises concentric rings, a balancing disc is sleeved on the outer sides of the concentric rings and is formed by connecting an inner annular disc frame and a plurality of supports which are circumferentially distributed on the outer portions of the concentric rings, included angles between every two adjacent supports are the same, a pressure sensor is arranged in each support, and a jack is arranged between every two adjacent supports.

The support is a rectangular support, and scale marks taking the circle center of the balance disc as a starting point are arranged on the edge of the support.

The concentric ring is provided with an axial threaded hole, and a mounting bolt is arranged in the threaded hole.

And equal-height cushion blocks are arranged between the adjacent brackets.

The bottom of the pressure sensor is provided with a supporting base.

Three supports are circumferentially distributed outside the balance disc.

The utility model has the advantages that the concentric ring, the balance disc, the pressure sensor and the jack are assembled into the large-scale mud pump impeller weighing type static balance device, the structure is simple, the position of the pressure sensor can be adjusted according to the diameter of the excircle of the impeller to be measured, the measurement radius of the unbalanced moment can be adjusted, the universality is good, the operation is safe and convenient, and the precision is reliable.

Drawings

FIG. 1 is a schematic structural diagram of a large-scale dredge pump impeller weighing type static balancing device of the utility model;

FIG. 2 is a partial sectional view of the large-scale mud pump impeller weighing type static balancing device in a use state;

FIG. 3 is a distribution diagram of the positions of three pressure sensors in the impeller weighing type static balancing device of the large-scale dredge pump.

In the figure, 1 concentric ring, 2 balance disc, 3 pressure sensor, 4 jack, 5 mounting bolt, 6 equal height cushion block, 7 supporting base, 8 impeller to be measured, 21 annular disc frame, 22 bracket.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

The utility model relates to a large-scale mud pump impeller weighing type static balancing device, which comprises a concentric ring 1, wherein a balancing disc 2 is sleeved outside the concentric ring 1, the balancing disc 2 is formed by connecting an inner annular disc frame 21 and three supports 22 which are circumferentially distributed outside, included angles between the adjacent supports 22 are the same, a pressure sensor 3 is arranged inside each support 22, a supporting base 7 is arranged at the bottom of each pressure sensor 3, and a jack 4 and an equal-height cushion block 6 are arranged between the adjacent supports 22.

The support 22 is a rectangular support, and the edge of the support is provided with scale marks taking the circle center of the balance disc 2 as a starting point, so that the position of the pressure sensor 3 in the support 22 can be accurately adjusted.

The concentric ring 1 is provided with an axial threaded hole, and a mounting bolt 5 is arranged in the threaded hole and used for fixedly connecting the concentric ring 1 with the mud pump impeller.

When the large-scale dredge pump impeller weighing type static balancing device is used, the operation steps are as follows:

(1) referring to fig. 2, firstly, a large dredge pump impeller weighing type static balancing device is placed on a platform, then the shaft end of an impeller 8 to be measured is placed on the top of the weighing type static balancing device upwards, and the impeller 8 to be measured is enabled to be supported on a cushion block 6 with equal height;

(2) fixing the concentric ring 1 and the impeller 8 to be tested together by using a mounting bolt 5, so that the circle center of the impeller 8 to be tested is superposed with the circle center of the balance disc and is close to the outer circle of the lower end surface of the impeller to be tested;

(3) lifting the jacks 4 to enable the impeller 8 to be tested to bear the weight of the three jacks 4, then synchronously descending the three jacks to enable the impeller to be tested to bear the weight of the three groups of pressure sensors, and checking the horizontal error of the impeller to be tested;

(4) lifting a jack, jacking an impeller to be tested, and enabling three groups of pressure sensors to return to zero;

(5) the jack is synchronously descended again to ensure that the impeller to be measured bears the weight of the three groups of pressure sensors, and the data G on the 3 groups of pressure sensors is read_A1、G_B1、G_C1；

(6) Repeating the steps (4) and (5) for two times, and respectively recording 2 groups of data G_A2、G_B2、G_C2And G_A3、G_B3、G_C3；

(7) Repeating the steps (4), (5) and (6) for three times after rotating the impeller to be tested by 180 degrees, and recording to obtain three groups of data G'_A1、G’_B1、G’_C1，G’_A2、G’_B2、G’_C2And G'_A3、G’_B3、G’_C3；

(8) As shown in FIG. 3, when 3 pressure sensors are loaded, three sets of data G are read_A、G_B、G_CAfter decomposing 3 readings to X, Y axes, the method can be obtained

G_X＝G_A-(G_Bsin30°+G_Csin30°) (1)

G_Y＝G_Ccos30°-G_Bcos30° (2)

The total weight G of the impeller can be obtained according to the formulas (1) and (2)_{General assembly}And angle θ:

θ＝arctan(G_X/G_Y) (4)

(9) respectively averaging the results of the previous three measurements and three groups of data measured after the impeller to be measured rotates by 180 degrees, and then averaging again to obtain the unbalance and the angle of the impeller at the distribution circle of the pressure sensor;

(10) according to the determined unbalance angle orientation of the impeller to be measured, removing the weight G at the proper non-processing surface position of the impeller_{Fruit of Chinese wolfberry}According to the moment balance principle, the method is calculated according to the following formula:

wherein R is_MeasuringDistribution of the radius of the circle, R, for the pressure sensor_{Fruit of Chinese wolfberry}Radius of actual de-weight of impeller to be measured, G_MeasuringIs the weight bias measured at the pressure sensor.

(11) After the weight is removed, the impeller is subjected to static balance measurement until the weight deviation is reduced to an allowable range.

Claims (6)

1. Large-scale dredge pump impeller weighing type static balancing unit, its characterized in that, including concentric ring (1), concentric ring (1) outside cover is equipped with balance disk (2), and balance disk (2) are connected by a plurality of supports (22) of inside annular plate rail (21) and outside circumference distribution and are formed, and the contained angle between adjacent support (22) is the same, and support (22) inside is provided with pressure sensor (3), is provided with jack (4) between adjacent support (22).

2. The large dredge pump impeller weighing type static balancing device according to claim 1, characterized in that the support (22) is a rectangular support, and the edge of the support (22) is provided with a scale mark with the center of the balance disc (2) as the starting point.

3. A large dredge pump impeller weighing type static balancing device according to claim 1, characterized in that the concentric ring (1) is provided with axial threaded holes, and mounting bolts (5) are arranged in the threaded holes.

4. A large dredge pump impeller weighing type static balancing device according to claim 1, characterized in that, between the adjacent brackets (22), there is provided a pad block (6) with equal height.

5. A large dredge pump impeller weighing type static balancing device according to claim 1, characterized in that the pressure sensor (3) is provided with a support base (7) at the bottom.

6. A large dredge pump impeller weighing type static balancing device according to claim 1, characterized in that, three brackets (22) are circumferentially distributed outside the balancing disc (2).

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