KR102186081B1 - Jig device for thermal spray coating - Google Patents

Abstract

The present invention relates to a jig device for thermal spray coating, which installs first and second roller units having two rollers rotating at an upper portion of a bogie moving on the ground to be fixed at a specific position, continuously maintains a relative height of a roller unit of any one side with respect to the bogie, allows the height of a roller unit of the other side to be adjusted with respect to the bogie, and performs rotation in a state that a cylindrical part having a changeable diameter is inclined at a predetermined angle to perform thermal spray coating, such that a coating film having a uniform thickness is formed to improve quality and to lower the center of gravity so as to reliably perform the thermal spray coating.

Description

Jig device for thermal spray coating

The present invention relates to a jig device for thermal spray coating, and more particularly, a first roller part and a second roller part having two rollers rotating on the top of a bogie that can be moved along the ground and fixed at a specific position However, one roller part maintains a constant relative height to the bogie, and the other roller part allows the height of the bogie to be adjusted, so that the cylindrical parts with varying diameters are rotated while inclined at a certain angle. It is a jig device for thermal spray coating that can achieve stable thermal spray coating by lowering the center of gravity as well as improving quality by forming a coating film of uniform thickness by performing coating.

In general, large-scale wind turbines are installed at a height of several tens of meters above the ground and are mainly installed in windy mountains and coastal areas as a device that generates electricity using wind, and in recent years, many offshore wind turbines are installed. Has become.

These large wind turbines are large enough to reach tens of meters in size of the blades rotated by the wind, so the tubular body to support the large blades or the yaw bearings and pitch bearings installed to hold the rotating shaft of the blades bearing), brake disc (brake disc) and main shaft (main shaft) are inevitably larger, but the main shaft 100 shown in Fig. 1 stably supports the rotating blade with high centrifugal force. For this reason, since the size of the head part 101 is provided relatively larger than the size of the body part 102, the center of gravity that is focused toward the head part when the thermal spray coating is performed while rotating while the central axis of the main shaft is horizontal with respect to the ground. As a result, the main shaft falls off, increasing the risk of damage to the main shaft and safety accidents.

As a conventional technology related to a jig of a thermal spray coating or a painting device, there is a tube coating device proposed in Patent No. 10-1487315.

The patent includes a body provided with a wheel and a wheel drive unit for driving the wheel, a paint spraying part provided on the body and spraying paint while moving along an arc of the outer circumferential surface of the tube, provided on the outside of the tube, A painting unit for spraying paint on the outer circumferential surface of the tube while moving along the longitudinal direction of the tube; Each of the ends of the tube is supported so that the longitudinal direction of the tube is rotatable in the axial direction, and the busbar facing the ground of the tube supports the tube so that the painting unit is parallel to the copper line moving in the longitudinal direction of the tube. There is disclosed a tubular coating device including a turning roller capable of adjusting the height of the tubular body, and in which the coating unit paints the outer circumferential surface of the tubular body rotated by the turning roller. And the surface treatment of wind turbine parts such as the main shaft is insufficient.

On the other hand, as a prior art related to thermal spray coating, there is a surface treatment method using thermal spray coating and ultrasonic nanocrystal surface modification disclosed in Patent No. 10-1722239.

In the above patent, in addition to the possibility of occurrence of non-uniformity or porosity of the coating and a problem in the adhesion of the coating layer, post-treatment to recover the fatigue of the object and modify the surface due to the coating operation was not considered at all. In the surface treatment method using thermal spray coating and ultrasonic nanocrystal surface modification configured to solve the problems of conventional surface treatment methods using the thermal spray coating technology of, comprising: preparing an object to be subjected to surface treatment; Performing a thermal spray coating (TSC) to impart desired mechanical properties to the object prepared in the step of preparing the object; Performing an ultrasonic nanocrystal surface modification (UNSM) on the surface of the object on which the thermal spray coating has been performed in the step of performing the thermal spray coating (TSC); And performing a finishing operation in which a treatment for completing a final product is performed by performing a finishing treatment including painting or surface treatment on the object on which the thermal spray coating and the ultrasonic nanocrystal surface modification (UNSM) have been performed. By being configured, by performing ultrasonic nanocrystal surface modification (UNSM) treatment on the surface of the object on which the thermal spray coating has been performed, to remove non-uniformity or porosity existing on the surface of the object and to improve the adhesion of the coating layer. Thereby preventing the occurrence of defects in the thermal spray coating process, recovering or improving the reduced strength and hardness of the object due to high temperature and high pressure in the thermal spray coating process, and mechanically including fatigue, friction, and wear. It is configured to improve performance, and the surface treatment method includes the thermal spray coating (TSC) and the ultrasonic wave for each coating layer when forming a plurality of coating layers through the thermal spray coating (TSC). It is configured to perform the nanocrystal surface modification (UNSM) continuously for each layer, or to perform the ultrasonic nanocrystal surface modification (UNSM) after forming each of the coating layers through the thermal spray coating (TSC), and , The surface treatment method, when performing the thermal spray coating (TSC) on the object, adding the ultrasonic nanocrystal surface modification (UNSM) after blasting to increase a specific surface area, or the blasting process Except for, it is configured to increase the adhesion of the coating layer by immediately adding the ultrasonic nanocrystal surface modification (UNSM).In addition, the surface treatment method includes the ultrasonic nanocrystal after thermal spray coating (TSC) on the base material. By performing surface modification (UNSM), it is configured to increase the life of the coating layer, thereby extending the period of the coating operation to reduce the overall cost.In addition, the surface treatment method includes abrasion or damage during use. After the thermal spray coating (TSC) on the damaged part of the part, the ultrasonic wave Thermal spray coating and ultrasonic nanocrystal surface, characterized in that it is configured to improve the performance and life of not only a single part but also the entire device by being configured to restore damaged parts by performing nanocrystal surface modification (UNSM) A surface treatment method using modification has been proposed. In the case of thermal spray coating, a large area can be performed within an appropriate time, but in the case of ultrasonic nanocrystal surface modification, it is difficult to perform all surfaces in the case of large parts such as the main shaft of a large wind turbine. It is practically impossible because too much time is consumed.

Another prior art is the thermal spray coating method for zirconium tubes proposed in Patent Registration No. 10-1843308.

In the patent, the base 10 and the front and rear plates 12 and 14 respectively disposed at the front and rear of the base 10 and supporting the zirconium tube 30, and the front and rear plates 12 and 14 At least one is disposed between the zirconium tube 30 while preventing sagging of the zirconium tube 30 and at the same time rotating the zirconium tube 30 with the power of the motor 20 and located on the base 10, the vibration In the method of spray coating the surface of a zirconium tube using a spray coating device consisting of a plasma spray gun 40 that forms a spray coating layer on the surface of the zirconium tube 30 rotatably supported by the means 20, A sanding process 100 of sanding the surface of the zirconium tube 30 by spraying alumina powder on the surface of the zirconium tube 30 at an injection pressure of 2 to 3 kg/cm 2 with an inert gas pressure; A cleaning process 200 for removing impurities buried on the surface of the zirconium tube 30 that has been subjected to the sanding process 100; After supporting the zirconium tube 30 that has passed through the cleaning process 200 on the front and rear plates 12 and 14 and the vibration isolating means 30, the zirconium tube 30 is driven by the vibration isolating means 30 The plasma spray gun 40 is rotated at a rotational speed of 100 to 1050 rpm, and the plasma spray gun 40 is removed from the zirconium tube 30 by a distance of 100 to 150 mm, and the plasma is used along the length direction of the zirconium tube 30. While moving the case 40 at a speed of 80 to 150 mm/s, by injecting an inert gas into the plasma spraying case 40 to spray a plasma jet flame on the surface of the zirconium tube 30, the zirconium tube 30 Preheating step 300 of preheating between 80 and 120°C; The zirconium tube 30 that has passed through the preheating process 300 is rotated at a rotational speed of 800 to 1050 rpm by driving the vibration isolating means 20, and at the same time, the plasma spraying event 40 is 100 in the zirconium tube 30. Plasma jet flame sprayed from the plasma spray gun 40 while moving the plasma spray gun 40 at a speed of 80 to 150 mm/s along the length direction of the zirconium tube 30 while being separated by a distance of ~150 mm A thermal spray coating process of discharging metal chromium powder into the inside at a discharge pressure of 20 to 60 g/min to form a thermal spray coating layer having a thickness of 20 to 50 μm on the surface of the zirconium tube 30 through melting of the metal chromium powder ( 400) is a method of spray coating a zirconium tube, which is characterized by spraying alumina powder on the surface of the zirconium tube under the pressure of an inert gas and sanding, thereby increasing the cost of the sanding process and catching the zirconium tube. There may be a problem in that it is difficult to uniformly form the thickness of the thermal spray coating layer due to the thermal spray coating, as it takes more time to enter the surface treatment as it has to be moved separately because the spray is not performed on the side with the anti-vibration means. .

In addition, it is more difficult to form a thermal spray coating layer having a uniform thickness on the surface of the tube by performing thermal spraying by moving the position of the plasma spray incident at the same time as the zirconium tube rotates.

Korean Patent Publication No. 10-1487315 Korean Patent Publication No. 10-1722239 Korean Patent Publication No. 10-1843308

The present invention provides a jig device for thermal spray coating, but installs a first roller part and a second roller part having two rollers rotating on the top of a bogie that can be fixed to a specific position by moving along the ground, The roller part of the side maintains a constant relative height to the bogie, and the roller part on the other side allows the height of the bogie to be adjusted, so that the cylindrical parts with varying diameters are rotated while being inclined at a certain angle to perform thermal spray coating. It is an object of the present invention to provide a thermal spray coating jig device capable of stable thermal spray coating by forming a coating film having a uniform thickness to improve quality and to lower the center of gravity.

In addition, one side of the bogie is further provided with a rotational support unit provided with an insertion protrusion fitted into a groove formed in the part so that the part can stably rotate, preventing the cylindrical part from slipping arbitrarily or being separated from the jig, thereby increasing stability Another object is to provide a jig device for coating.

In addition, the second roller unit is configured to be moved in the longitudinal direction of the bogie along a rail fixedly installed on the bogie, so that it can respond to changes in the length of the main shaft, thereby providing a jig device for thermal spray coating with improved versatility. have.

A jig device for thermal spray coating according to the present invention is a jig device for thermal spray coating of a cylindrical part, a vehicle that can be fixed to the ground, a first roller portion fixedly installed on the top of the vehicle, and the first roller portion Consists of a second roller part fixedly installed on the top of the bogie apart from a certain distance, and rotating rollers that can be rotated by a driving device are installed in the first and second roller parts, respectively, so that the cylindrical parts rotate at a constant speed. It is characterized by being able to perform thermal spray coating while making it possible.

A jig device for thermal spray coating according to the present invention is provided with a first roller part and a second roller part having two rollers rotating on the top of a bogie that can be fixed at a specific position by moving along the ground, but one of the roller parts The relative height of the bogie is kept constant, and the roller on the other side allows the height of the bogie to be adjusted, so that the cylindrical parts with varying diameters are rotated while being inclined at a certain angle to achieve uniform thickness. It has a remarkable effect that stable thermal spray coating can be achieved by forming a coating film of and at the same time lowering the center of gravity by forming a coating film of Further provided with a rotation support unit installed, the cylindrical part is prevented from slipping or separating from the jig, and the effect of enhancing stability, and the second roller part so that it can be moved in the longitudinal direction of the bogie along the rail fixedly installed on the bogie. It has a remarkable effect of increasing versatility by configuring it to cope with the change in length of the main shaft.

1 is an exemplary configuration diagram of a main shaft for a wind power generator
Figure 2 is an exemplary view of the use state of the present invention
Figure 3 is a side view of Figure 2
Figure 4 is a separate configuration diagram of the present invention
Figure 5 is a partial configuration diagram of the present invention
6 and 7 are diagrams illustrating another embodiment of the present invention
Figure 8 is a view of another embodiment of the present invention

The present invention relates to a jig device for thermal spray coating, and more particularly, a first roller part and a second roller part having two rollers rotating on the top of a bogie that can be moved along the ground and fixed at a specific position However, one roller part maintains a constant relative height to the bogie, and the other roller part allows the height of the bogie to be adjusted, so that the cylindrical parts with varying diameters are rotated while inclined at a certain angle. It is a jig device for thermal spray coating that can achieve stable thermal spray coating by lowering the center of gravity as well as improving quality by forming a coating film of uniform thickness by performing coating.

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

Figure 2 is an exemplary use state of the present invention, Figure 3 is a side view of Figure 2, Figure 4 is a separate configuration diagram of the present invention, the jig device for spray coating according to the present invention is a jig for spray coating of cylindrical parts In the device, a truck 1 that can be fixed to the ground, a first roller part 10 fixedly installed on the top of the truck 1, and a truck 1 separated by a predetermined distance from the first roller part 10 ) Consisting of a second roller part 20 fixedly installed on the upper part, the first roller part 10 and the second roller part 20 are each provided with a rotating roller that can be rotated by a driving device, It is characterized by being able to perform thermal spray coating while rotating cylindrical parts at a constant speed.

First, it is preferable to configure the bogie (1) so that it can be moved while the wheels (3) are installed and heavy objects are mounted, and a rail is installed on the ground for the stable movement of the bogie (1), and the bogie is moved along the rail. Can be configured to move.

The first roller part 10 and the second roller part 20 are fixedly installed on the top of the bogie 1, and in the present invention, a roller part installed on the head part 101 side of the main shaft 100, which is a cylindrical part, is provided. It is designated as the first roller part 10, and the roller part installed on the side of the body part 102 is designated as the second roller part 20.

Each of the first roller unit 10 and the second roller unit 20 is provided with a rotating roller that can be rotated by a driving device, and a robot, that is, an articulated robot, is able to rotate the cylindrical part. As it moves along, you can perform thermal spray coating.

Referring to FIG. 3, since the height of the second roller part 20 can be adjusted on the bogie 1, the component can be rotated while the central axis of the component is inclined with respect to the ground.

That is, in the case of the main shaft 100 used in the illustrated wind turbine, the diameter of the head 101 is larger than the diameter of the body 102 in order to stably support the blade rotating with a strong centrifugal force by the action of wind power. Since the center of gravity of the main shaft 100 is relatively large and thus the center of gravity of the main shaft 100 is focused on the head part 101, the main shaft 100 is rotated while raising the center of the head part 101 of the main shaft to the center of the body part 102. When) rotates, it can be prevented from falling by inclining toward the head unit 101.

Referring to FIG. 4, two rollers installed in the first roller unit 10 include a driving roller 11 rotated by a motor 14, a belt 15, and a pulley 16, and the driving roller 11 It is a driven roller 12 rotated by the main shaft 100 rotated by.

In addition, the second roller unit 20 may also be configured to rotate one roller by a motor. In this case, the rotation speed of the driving roller 11 installed on the first roller unit 10 and the second roller unit ( In the case of products having different diameters of the main shaft body, the rotational speed of the rollers 21 installed in 20) may be different from each other.

In addition, one side of the bogie 1 is further provided with a rotation support 30 provided with an insertion protrusion 32 fitted into a central hole 103 formed in the component so that the component can stably rotate.

That is, the rotation support part 30 is fixed by being inserted into the center hole 103 formed in the body part 102 of the main shaft 100 by installing the insertion protrusion 32, and in this state, the main shaft 100 is rotated. Thus, when the main shaft 100 rotates, it is possible to prevent slipping and falling out of the first roller unit 10 and the second roller unit 20.

Here, the insertion protrusion 32 is supported by the bearing 33 so that friction against the rotation of the insertion protrusion 32 can be minimized, and the bearing 33 is a rotation support part ( Since it is fixed to the column 31 of 30), the height can be adjusted.

In addition, the insertion protrusion 32 of the rotation support part 30 may be configured such that the central axis of the insertion protrusion 32 can adjust the inclination within a certain range with respect to the ground in order to correspond to the inclination of the part.

That is, the insertion protrusion 32 is supported by the bearing 33, but the bearing housing 34 can be installed so that the position can be adjusted up and down with respect to the column 31 as well as angle adjustment. By fixing to the column using a ball joint or a universal joint on one side of the protrusion, it can be configured to respond to the inclination of the main shaft while reducing friction for rotation.

In addition, the second roller part 20 is configured to be moved in the longitudinal direction of the bogie 1 along the rail 2 fixedly installed on the bogie 1, so that the length of the main shaft 100 is relatively long or Even in a short case, the thermal spray coating can be performed while rotating with a single jig device, thereby increasing the versatility.

In the case of the second roller part 20, the height can be adjusted using a jack 22 formed under the frame 23, and the jack 22 includes a screw jack and a rack jack. Alternatively, an oil pressure jack may be used, and in some cases, it may be configured to adjust the height of the frame 23 using bolts and nuts.

In addition, referring to FIG. 5, the two rollers 21 installed on the second roller part 20 can be moved along the frame 23 so that the distance between the two roller rotation center axes can be adjusted, You can adjust the tilt of the part by adjusting the distance between the rotation center axes.

That is, while adjusting the height of the entire second roller part 20 using the jack 22 installed between the frame 23 and the bogie 1, the distance between the two rollers is the roller 32 along the frame 23 The inclination can be finely adjusted even when the main shaft 100 is seated by adjusting by moving.

Incidentally, when the distance between the two rollers 21 installed in the second roller part 20 is brought closer (indicated by a dotted line), the height of the body part 102 increases, so that the central axis of the main shaft 100 and the The acute angle formed by the ground will be reduced, and if the distance between the two rollers installed on the second roller unit 20 is increased (indicated by a solid line), the height of the body unit 102 is lowered, thereby reducing the center of the main shaft 100 Since the acute angle formed by the axis and the ground increases, the inclination of the main shaft 100 can be finely adjusted using this principle.

The two rollers 21 installed on the second roller part 20 may allow the rollers to move along the frame, and as shown in FIG. 6, a screw having threads extending in opposite directions between the two rollers 21 It can be installed between the frames supporting the two rollers and configured to adjust the distance between the rollers according to the rotation of the screw. In this case, since the central axis between the two rollers can always maintain a constant position, there is an advantage that the inclination of the main shaft can be adjusted while the centers of the first roller unit 10 and the second roller unit 20 are aligned. .

7 is an exemplary view of another embodiment of the present invention, the outer surface of the cylindrical part in contact with the first roller part 10 and the second roller part 20 is wrapped by a synthetic paper 40 having adhesive force, and the composite The paper 40 is fixed to the cylindrical part by the iron band 41.

That is, in the case of the main shaft 100, the part where the bearing is coupled for rotation does not need to be spray coated, and there is a part where the spray coating should not be performed for stable tolerance management. Masking is performed by performing thermal spray coating in the state covered by 40).

In addition, the synthetic paper 40 is stably fixed to the main shaft 100 by the iron band 41 to prevent the synthetic paper from peeling off by the roller.

8 is another exemplary embodiment of the present invention, the first roller part 10 or the second roller part 20 does not have a separate motor, and the rotation support part 30 includes a motor 35 and a belt ( 36) is provided to rotate the main shaft by rotating the insertion protrusion 32 fitted in the center hole 103 of the main shaft.

In this configuration, the first roller part 10 or the second roller part 20 only adjusts the inclination of the main shaft, and the driving force for rotation of the main shaft is generated by the motor 35 installed in the rotation support part 30. By doing so, the configuration of the bogie can be more simply configured, and installation and maintenance of the rollers respectively installed on the first roller unit 10 and the second roller unit 20 can be made conveniently.

In addition, in the illustrated embodiment, the insertion protrusion 32 itself is extended to be driven by the belt 36, but in some cases, a pulley is further provided outside the insertion protrusion 32, or by the insertion protrusion and the coupling. With a combined rotation shaft, the insertion protrusion can be configured to rotate by rotation of the rotation shaft, and such a coupling prevents damage of the insertion protrusion when a strong load is applied that obstructs the rotation of the main shaft.

In the end, the spray coating jig device according to the present invention is provided with a first roller part and a second roller part having two rollers rotating on the top of a bogie that can be fixed to a specific position by moving along the ground, The roller part maintains a constant relative height to the bogie, and the other roller part allows the height of the bogie to be adjusted, so that the cylindrical parts with varying diameters rotate while being inclined at a certain angle, and spray coating is performed uniformly. By forming a coating film of one thickness to improve quality and at the same time to lower the center of gravity, there is a remarkable effect that stable thermal spray coating can be achieved, and on one side of the bogie, it is inserted into a groove formed in the part so that the part can be stably rotated. Further provided with a rotational support portion provided with an insertion protrusion, the second roller portion can be moved in the longitudinal direction of the bogie along the rail fixedly installed on the bogie by preventing the cylindrical parts from sliding or separating from the jig. It has a remarkable effect of increasing versatility by configuring it so that it can respond to changes in the length of the main shaft.

1. Bogie 2. Rail
3. Wheel
10; 1st roller part
11. Drive roller 12. Driven roller
13. Support frame 14. Motor
15. Belt 16. Pulley
20; 2nd roller part
21. Roller 22. Jack
23. Frame 24. Screw
30; Rotating support
31. Column 32. Insertion protrusion
33. Bearing 34. Bearing Housing
35. Motor 36. Belt
40. Synthetic paper 41. Iron band
100; Main shaft
101. Head part 102. Body part
103. Central Hall

Claims (7)

In a jig device for thermal spray coating of cylindrical parts,
A bogie 1 that can be fixed to the ground, a first roller portion 10 fixedly installed on the top of the bogie 1, and a fixed distance from the first roller portion 10 to the top of the bogie 1 It consists of a second roller part 20 to be installed, and each of the first roller part 10 and the second roller part 20 is provided with rotating rollers that can be rotated by a driving device, so that the cylindrical parts Spray coating can be performed while rotating at speed,
One side of the bogie (1) is further provided with a rotation support (30) provided with an insertion protrusion (32) fitted into the central hole (103) formed in the component so that the component can be stably rotated. Jig device.
The method of claim 1,
The second roller part 20 is a thermal spray coating jig device characterized in that the height of the second roller part 20 can be adjusted on the bogie 1 so that the component can be rotated while the central axis of the component is inclined with respect to the ground.
delete The method of claim 1,
The insertion protrusion 32 of the rotation support part 30 is a thermal spray coating jig characterized in that the central axis of the insertion protrusion 32 can adjust the inclination within a certain range with respect to the ground in order to correspond to the inclination of the part. Device.
The method of claim 1,
The second roller part 20 is a thermal spray coating jig device, characterized in that it can be moved along a rail (2) fixedly installed on the bogie (1) in the longitudinal direction of the bogie.
The method of claim 2,
The two rollers 21 installed on the second roller part 20 can be moved along the frame 23 so that the distance between the two rollers 21 rotation center axis can be adjusted, and the A jig device for thermal spray coating characterized by adjusting the distance to adjust the slope of the part.
The method of claim 1,
The outer surfaces of the cylindrical parts in contact with the first roller part 10 and the second roller part 20 are wrapped by a synthetic paper 40 having adhesive force, and the synthetic paper 40 is wrapped by an iron band 41. A jig device for thermal spray coating characterized by being fixed to a cylindrical part.

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