CN113339313A - Centrifugal adjusting method for odd asymmetric radial tile gaps of shaft seal type nuclear main pump - Google Patents

Abstract

The invention relates to a centrifugal adjusting method for odd asymmetric radial tile gaps of a shaft seal type nuclear main pump of a nuclear power station, which is used for completing radial bearing assembly and comprises the following steps: bearing room (1), slider (2), spherical (3), slider adjusting bolt (4), hexagon nut (5), radial tile (7), spherical screw (8), hexagon head screw (9), adjusting screw gasket (10), tile base (11) are accomplished according to the drawing assembly, make slider (2) and spherical (3) laminating, and hexagon nut (5) are in the state of loosening. The invention can ensure the coaxiality between the radial tiles and the gap between the bearing sleeve and the radial tiles, and solves the problems that the bearing sleeve and the radial tiles are not coaxial due to the asymmetrical structure and odd distribution of the radial tiles and the gap between the bearing sleeve and the radial tiles is not uniform due to inaccurate adjustment of the radial tiles.

Description

Centrifugal adjusting method for odd asymmetric radial tile gaps of shaft seal type nuclear main pump

The technical field is as follows:

the invention relates to a centrifugal adjusting method for radial tile gaps of an odd number asymmetric structure of a shaft seal type nuclear main pump of a nuclear power station.

Background art:

the radial bearing of the shaft-sealed nuclear main pump of the nuclear power station is a main component of a bidirectional thrust bearing and is also a key component of the nuclear main pump, and the control of the odd number of radial tile gaps with asymmetric structures is particularly important for normal operation of the shaft-sealed nuclear main pump and localization of a main pump manufacturing technology. The accurate adjustment of the gap between the odd number asymmetric structure radial tiles of the shaft seal type nuclear main pump is always a technological problem. The adjustment process of the gap of the traditional radial tile with the even-number symmetrical structure is not suitable for the novel radial tile with the odd-number asymmetrical structure, the adjustment mode is a cross-shaped symmetrical method, and when the process is used for the radial tile with the odd-number asymmetrical structure, obvious quality defects can be generated, and the adjustment process comprises the following steps: the internal disalignment of circle in all radial tiles, the not equidirectional radial tile is inhomogeneous with bearing sleeve's clearance, thereby lead to radial tile and bearing sleeve clearance uncontrolled and unable accurate measurement, lead to the bearing sleeve to pack into in the radial tile even, radial tile need readjust the clearance, and the result of readjustment is still not accurate enough, the loss and the time limit for a project delay of cost have been brought, even pack into and also probably cause bearing sleeve eccentric, thereby make bearing sleeve and radial tile eccentric wear, produce the metal debris, the oil temperature oil pressure is unusual, the main pump vibration is too big, then more serious can cause nuclear power plant's accident.

The invention content is as follows:

the invention aims to disclose a centrifugal adjusting method for an odd number of asymmetric radial tile gaps of a shaft seal type nuclear main pump, which has the advantages of high reliability, high precision, high efficiency and stable data. The technical scheme of the invention is as follows: adopting a taper tool to adjust and measure the gap with a feeler gauge so as to enable each radial tile to be coaxial and determine the gap between a bearing sleeve and the radial tile, and comprising the following steps:

1) and finishing the radial bearing assembly: the bearing assembly device comprises a bearing chamber (1), a sliding block (2), a spherical part (3), a sliding block adjusting bolt (4), a hexagon nut (5), a radial tile (7), a spherical part screw (8), a hexagon head screw (9), an adjusting screw gasket (10) and a tile base (11), wherein the assembly is completed according to a drawing, so that the sliding block (2) is attached to the spherical part (3), and the hexagon nut (5) is in a loose state;

2) the slider adjusting bolt (4) is seen from the upward view direction, the slider adjusting bolt (4) is rotated clockwise, the slider (2) is lifted, the distance between the slider adjusting bolt (4) and the end face of the hexagon nut (5) is H, and the distance is recorded

H＝5mm±0.1mm

3) Putting a conical tool (6) in the middle of a radial tile (7), pressing the conical tool (6) to enable the conical tool (6) to be in contact with the radial tile (7), measuring whether a clearance A between the conical tool (6) and each radial tile (7) meets A & lt 0.02mm by using a feeler gauge (12), if the clearance A exceeds 0.02mm, clockwise rotating a sliding block adjusting bolt (4) to enable a sliding block (2) to be lifted, and enabling the radial tile (7) to move towards the conical tool (6) to enable the clearance A between the conical tool (6) and each radial tile (7) to meet A & lt 0.02 mm;

4) rotating the sliding block adjusting bolt (4) counterclockwise for a quarter of a turn, lowering the height of the sliding block (2), pressing the conical tool (6) downwards to enable the conical tool (6) to be in contact with the radial tiles (7), enabling the radial tiles (7) to move towards the bearing chamber (1), measuring whether a clearance A between the conical tool (6) and each radial tile (7) meets A & lt 0.02mm by using a feeler gauge (12), and if the clearance A exceeds 0.02mm, rotating the sliding block adjusting bolt (4) clockwise, lifting the sliding block (2) to enable the radial tiles (7) to move towards the conical tool (6) to enable the clearance A between the conical tool (6) and each radial tile (7) to meet A & lt 0.02 mm;

5) and (4) repeating the step (2), gradually reducing the height of the sliding block (2) to enable all the radial tiles (7) to synchronously move towards the bearing chamber (1) until the conical tool (6) completely falls into the radial tiles (7), enabling the clearance A to meet the requirement that A is less than 0.02mm, and locking the hexagonal nut (5), so that the centrifugal adjustment work of the radial tile clearance is completed.

The working principle of the invention is as follows:

the working process and principle of the invention are that firstly, the wedge-shaped sliding block with small top and big bottom is lifted to the highest, and the thickness of the sliding block with the height of the spherical part is changed to push the spherical part and the radial tile to move towards the conical tool, so that the distance between the radial tile and the center is minimized. The spherical part is in spherical contact with the radial tile and has a certain degree of rotational freedom, so that the radial tile can freely move on the tile base in a horizontal direction. Then put into radial tile with the toper instrument, use the feeler gauge to measure and preliminary adjustment makes all radial tiles coaxial, then through screwing the slider adjusting bolt and reduce the slider height in step, the slider thickness of spherical part place height diminishes simultaneously, radial tile and spherical part receive the toper instrument dead weight and press down the extrusion force that produces after, can be automatic move to the bearing room simultaneously to make radial tile internal diameter grow, make it the same with the maximum diameter of toper instrument finally, and the maximum diameter of toper instrument is final radial tile clearance adjustment size promptly. After the inner diameter of the radial tile is enlarged each time, the clearance between the radial tile and the conical tool is measured by using the feeler gauge, and the radial tile with the out-of-tolerance clearance is adjusted to meet the requirement, so that all the radial tiles are always coaxial. And repeating the adjusting and measuring steps, gradually reducing the height of the sliding block, amplifying the inner diameter of the radial tile, and measuring the gap between the radial tile and the conical tool and adjusting the gap to be qualified after amplifying the inner diameter of the radial tile every time in order to control all the radial tiles to be coaxial.

The invention has the technical effects that:

when a shaft system of the nuclear main pump rotates, the shaft system runs in the theoretical running center of the main pump, a motor shaft providing power in the shaft system penetrates through the radial bush and extends to the lower part of the bidirectional thrust bearing, the motor shaft runs in the center of the radial bearing, the center of the radial bearing is in the running center of the main pump, and the coaxiality of the radial bearing and a bearing sleeve on the motor shaft determines whether the center of the motor shaft is accurately positioned in the theoretical running center of the main pump. The odd number of the radial tiles which are distributed asymmetrically are contact parts of the radial bearing and a motor shaft, the clearance between the radial tiles and the bearing sleeve and the coaxiality between the radial tiles determine the coaxiality between the radial tiles and the motor shaft, if the clearance between the radial tiles and the bearing sleeve is not uniform, the radial bearing and the motor shaft are not coaxial, the center of the motor shaft is not positioned at the running center of a main pump, if the center of the motor shaft deviates from the rotating center position of the main pump, the inner circle of the radial tiles is eccentrically ground when a shafting runs, and therefore damage to the radial tiles, generation of metal scraps, abnormal oil temperature and pressure and vibration increase of the main pump or more serious accidents are caused.

The invention creatively adopts a taper tool to adjust and measure the clearance with the feeler gauge, thereby determining the clearance between the bearing sleeve and the radial tile and ensuring the radial tiles to be coaxial. The method has the advantages that the inner diameter of the radial tile can be accurately adjusted, and the gap between the radial tile and the bearing sleeve can be accurately controlled, so that the radial tile and the motor shaft are ensured to be coaxial. And secondly, after the adjustment in the step 4), the clearance between the radial tile and the conical tool is required to be measured by using a feeler gauge to be less than 0.02mm, so that the coaxiality between the radial tiles has accurate data, the accuracy of the adjustment of the radial tiles is improved, and the radial tiles in the radial bearing in the traditional method have uncertain data and can not be accurately measured due to too large freedom. Thirdly, the method improves the adjusting efficiency and reduces the assembling time due to the accuracy of adjusting the radial tile gap. And fourthly, the method is superior to the traditional method, the radial tile gap can be accurately adjusted by using a simple conical tool and a feeler gauge, and the condition that the traditional method is repeatedly operated and cannot accurately adjust the size to cause rework is avoided. Fifthly, due to the fact that the accuracy of the method for adjusting the gap between the radial tiles reduces the vibration value of the whole main pump caused by the fact that the radial tiles and the motor shaft are not coaxial, abrasion of a radial bearing is reduced, the service life is prolonged, and the risk of shutdown of the shaft seal type nuclear main pump is reduced.

Description of the drawings:

FIG. 1 radial bearing Assembly drawing

FIG. 2 schematic diagram of adjusting bolt distance of slider

FIG. 3 schematic view of the gap between the tapered tool and the radial shoe

The specific implementation mode is as follows:

the centrifugal adjusting method for the radial tile gap of the axial seal type nuclear main pump of the nuclear power station with the odd number asymmetric structure is high in reliability, high in precision, high in efficiency and stable in data. In order to achieve the purpose, the scheme is as follows: centrifugal adjusting method for odd asymmetric radial tile gaps of shaft seal type nuclear main pump

As shown in fig. 1, the clearance is measured with a feeler gauge using a taper tool to make the radial shoes coaxial and determine the clearance between the bearing sleeve and the radial shoes, the method comprising the following steps:

1) and finishing the radial bearing assembly: the bearing chamber 1, the sliding block 2, the spherical part 3, the sliding block adjusting bolt 4, the hexagon nut 5, the radial tile 7, the spherical part screw 8, the hexagon head screw 9, the adjusting screw gasket 10 and the tile base 11 are assembled according to a drawing, so that the sliding block 2 is attached to the spherical part 3, and the hexagon nut 5 is in a loose state;

2) looking at the slide adjusting bolt 4 from the bottom view direction of fig. 2, rotating the slide adjusting bolt 4 clockwise to lift the slide 2, so that the distance between the slide adjusting bolt 4 and the end face of the hexagon nut 5 is H, and recording

H＝5mm±0.1mm

3) Putting a conical tool 6 in the middle of the radial tiles 7, pressing the conical tool 6 to enable the conical tool 6 to be in contact with the radial tiles 7, measuring whether a clearance A between the conical tool 6 and each radial tile 7 meets A & lt 0.02mm by using a feeler gauge 12, and if the clearance A exceeds 0.02mm, clockwise rotating the sliding block adjusting bolt 4 to enable the sliding block 2 to be lifted, enabling the radial tiles 7 to move towards the conical tool 6, and enabling the clearance A between the conical tool 6 and each radial tile 7 to meet A & lt 0.02 mm;

4) as shown in fig. 3, the slider adjusting bolt 4 is rotated counterclockwise a quarter turn, the height of the slider 2 is lowered, the taper tool 6 is pressed downward to make the taper tool 6 contact with the radial shoes 7, the radial shoes 7 move toward the bearing chamber 1, the feeler 12 is used to measure whether the gap a between the taper tool 6 and each radial shoe 7 satisfies a < 0.02mm, if the gap a exceeds 0.02mm, the slider adjusting bolt 4 is rotated clockwise, the slider 2 is raised, the radial shoes 7 move toward the taper tool 6, so that the gap a between the taper tool 6 and each radial shoe 7 satisfies a < 0.02 mm;

5) and repeating the step 4), gradually reducing the height of the sliding block 2 to enable all the radial tiles 7 to synchronously move towards the bearing chamber 1 until the conical tool 6 completely falls into the radial tiles 7, and locking the hexagonal nut 5 until the clearance A meets the requirement that A is less than 0.02mm, so that the centrifugal adjustment work of the radial tile clearance is completed.

Claims (1)

1. The centrifugal adjusting method of the odd asymmetric radial tile gap of the shaft seal type nuclear main pump is characterized by comprising the following steps:

adopting a taper tool to adjust and measure the gap with a feeler gauge so as to enable each radial tile to be coaxial and determine the gap between a bearing sleeve and the radial tile, and comprising the following steps:

1) and finishing the radial bearing assembly: the bearing assembly device comprises a bearing chamber (1), a sliding block (2), a spherical part (3), a sliding block adjusting bolt (4), a hexagon nut (5), a radial tile (7), a spherical part screw (8), a hexagon head screw (9), an adjusting screw gasket (10) and a tile base (11), wherein the assembly is completed according to a drawing, so that the sliding block (2) is attached to the spherical part (3), and the hexagon nut (5) is in a loose state;

2) the slider adjusting bolt (4) is seen from the upward view direction, the slider adjusting bolt (4) is rotated clockwise, the slider (2) is lifted, the distance between the slider adjusting bolt (4) and the end face of the hexagon nut (5) is H, and the distance is recorded

H＝5mm±0.1mm

3) Putting a conical tool (6) in the middle of a radial tile (7), pressing the conical tool (6) to enable the conical tool (6) to be in contact with the radial tile (7), measuring whether a clearance A between the conical tool (6) and each radial tile (7) meets A & lt 0.02mm by using a feeler gauge (12), if the clearance A exceeds 0.02mm, clockwise rotating a sliding block adjusting bolt (4) to enable a sliding block (2) to be lifted, and enabling the radial tile (7) to move towards the conical tool (6) to enable the clearance A between the conical tool (6) and each radial tile (7) to meet A & lt 0.02 mm;

4) rotating the sliding block adjusting bolt (4) counterclockwise for a quarter of a turn, lowering the height of the sliding block (2), pressing the conical tool (6) downwards to enable the conical tool (6) to be in contact with the radial tiles (7), enabling the radial tiles (7) to move towards the bearing chamber (1), measuring whether a clearance A between the conical tool (6) and each radial tile (7) meets A & lt 0.02mm by using a feeler gauge (12), and if the clearance A exceeds 0.02mm, rotating the sliding block adjusting bolt (4) clockwise, lifting the sliding block (2) to enable the radial tiles (7) to move towards the conical tool (6) to enable the clearance A between the conical tool (6) and each radial tile (7) to meet A & lt 0.02 mm;

5) and (4) repeating the step (2), gradually reducing the height of the sliding block (2) to enable all the radial tiles (7) to synchronously move towards the bearing chamber (1) until the conical tool (6) completely falls into the radial tiles (7), enabling the clearance A to meet the requirement that A is less than 0.02mm, and locking the hexagonal nut (5), so that the centrifugal adjustment work of the radial tile clearance is completed.

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