JP7233326B2 - INSPECTION DEVICE AND INSPECTION METHOD FOR WIND TURBINE EQUIPMENT - Google Patents

Description

The present invention relates to an inspection apparatus and an inspection method for wind turbine generators.

Wind turbines are being widely introduced as a pillar of renewable energy. A wind power generator consists of a blade, a nacelle, and a tower. Wind power installations are exposed to wind and weather, which places loads on the components of the wind power installation. A load causes fatigue-related damage to parts of a wind turbine generator, and Patent Document 1, for example, proposes a technique for detecting the damage.

In Patent Document 1, blades that receive wind, a nacelle that supports the blades, and a yaw drive unit that rotates the nacelle are provided, and a tower that supports them is arranged.

Threads are laid on the blades and the tower, respectively, and when the blades and towers are damaged, the threads are torn.

Further, for example, Patent Document 2 has been proposed as a flaw detector for an inspection object. In Patent Literature 2, an object to be inspected is heated, discontinuity of temperature distribution of the object to be inspected is measured by an infrared detector, and defects in the object to be inspected are determined.

Special Table 2014-509705 JP-A-3-39644

In the wind turbine generator, the center of rotation of the nacelle coincides with the central axis of the tower. The nacelle supports the blades and houses the gearbox and generator. Since the mounting position and size of the gearbox and generator differ depending on the specifications of the wind turbine generator, the center of gravity of the nacelle is shifted from the central axis of the tower. Therefore, a bending moment is always generated in the tower. Also, as the nacelle rotates with respect to the tower, the location of the bending moment applied to the tower also changes. Under repeated bending moments, tower connections can experience fatigue damage. In addition, the tower may have hidden manufacturing defects due to poor construction during manufacturing. Early detection and repair of defects such as fatigue damage and manufacturing defects leads to extension of the life of the wind turbine generator.

In the technique described in Patent Document 1, the damage is identified by the breakage of the yarn, but the damaged location can only be detected directly under the yarn laid, and many yarns are laid to identify the damaged location. There is a need. Therefore, in Patent Literature 1, there is a problem that the thread laying workability is complicated and the cost associated with the laying work increases. Furthermore, no consideration is given to identifying the defective portion while the nacelle is rotating, making it difficult to improve reliability.

Moreover, in the technique described in Patent Document 2, it is necessary to heat the inspection target, and it is difficult to heat a large-sized device such as a wind power generator. was unsuitable. Furthermore, no consideration is given to identifying the defective portion while the nacelle is rotating, making it difficult to improve reliability.

SUMMARY OF THE INVENTION An object of the present invention is to provide an inspection apparatus and an inspection method for a wind power generator that suppresses an increase in operating costs and improves reliability.

In order to achieve the above object, in one aspect of the present invention, a blade that rotates in response to wind, a nacelle that supports the weight of the blade, and a plurality of members are connected to each other to turn the nacelle. a tower supported by the tower, a defect detection device for detecting defects in the connecting portion of the tower, moving means for moving the defect detection device, and driving means for rotating the nacelle , wherein the moving means is the driving The defect detection device is moved in accordance with the turning motion of the means , and the defect detection device detects the defect based on the open state of the connecting portion of the tower .

ADVANTAGE OF THE INVENTION According to this invention, the inspection apparatus and inspection method of a wind power generator which suppressed the increase in operation cost and improved reliability can be provided.

It is the general view which showed the wind power generator. 1 is a schematic external view of a wind turbine generator according to a first embodiment of the present invention; FIG. FIG. 6 is a schematic external view of a wind turbine generator according to a second embodiment of the present invention; FIG. 11 is a schematic external view of a part of a wind turbine generator according to a third embodiment of the present invention; FIG. 11 is a schematic external view of a wind turbine generator according to a fourth embodiment of the present invention; FIG. 11 is a schematic external view of a part of a wind turbine generator according to a fifth embodiment of the present invention; FIG. 11 is a schematic external view of a wind turbine generator according to a sixth embodiment of the present invention; FIG. 11 is a schematic external view showing a part of a wind turbine generator according to a seventh embodiment of the present invention; FIG. 11 is a schematic external view of a wind turbine generator according to an eighth embodiment of the present invention; FIG. 20 is a schematic external view showing a part of the wind turbine generator according to the ninth embodiment of the present invention; FIG. 11 is a schematic external view of a wind turbine generator according to a tenth embodiment of the present invention; FIG. 20 is a schematic external view showing a part of the wind turbine generator according to the eleventh embodiment of the present invention; FIG. 21 is a schematic external view of a wind turbine generator according to a twelfth embodiment of the present invention; FIG. 21 is a schematic external view of a tower of a wind turbine generator according to a thirteenth embodiment of the present invention; FIG. 21 is a schematic external view of a tower of a wind turbine generator according to a fourteenth embodiment of the present invention; FIG. 20 is a schematic external view of a wind turbine generator according to a fifteenth embodiment of the present invention; FIG. 21 is a schematic external view of a wind turbine generator according to a sixteenth embodiment of the present invention; FIG. 21 is a schematic external view of a wind turbine generator according to a seventeenth embodiment of the present invention;

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the following specific examples are merely illustrations, and do not limit the content of the invention.

A first embodiment of the present invention will be described with reference to FIGS. 1 and 2. FIG. FIG. 1 is an overall view showing a wind turbine generator. In FIG. 1, the wind turbine generator is generally composed of blades 1 that rotate under the wind, a nacelle 2 that supports the load of the blades 1, and a tower 3 that supports the nacelle 2 so that it can turn. The nacelle 2 is rotatably supported in the horizontal plane with respect to the tower 3 by driving means (not shown) installed inside the tower 3 . The tower 3 is constructed by connecting a plurality of members. The tower 3 is formed by, for example, joining a plurality of cylindrical members by welding to form a tower member, stacking a plurality of tower members in the vertical direction, and connecting and fixing portions of the tower members facing each other with bolts. The blades 1 are connected to a generator 23 via a main shaft 21 and a gearbox 22 . A gearbox 22 and a generator 23 are arranged inside the nacelle 2 .

In the wind turbine generator, the nacelle 2 turns on the tower 3 according to the direction of the wind, and the blades 1 rotate under the force of the wind. The rotation of the blades 1 is transmitted to the generator 23 after being increased to a rotation speed suitable for the generator 23 via the gearbox 22 . The electrical energy generated by the rotation of the generator 23 is rectified by a power converter (not shown), further regulated in voltage by a transformer (not shown), and sent to the power system.

A turning center TC of the nacelle 2 turning on the tower 3 coincides with the central axis CA of the tower. The nacelle 2 supports the blades 1 and incorporates a gearbox 22 and a generator 23 . Since the mounting positions and sizes of the gearbox 22 and the generator 23 differ depending on the specifications of the wind turbine generator, the center of gravity of the nacelle 2 is shifted from the central axis CA of the tower 3 . Therefore, a bending moment is always generated in the tower 3 . As the nacelle 2 rotates with respect to the tower 3, the position of the bending moment applied to the tower 3 also changes. Under repeated bending moments, tower connections can be damaged or bolted loose. Also, the tower connections may hide manufacturing defects due to poor connections. Finding these defects early and repairing them leads to extension of the life of the wind turbine generator. Furthermore, identifying the defective portion while the nacelle 2 is rotating leads to an improvement in reliability. Means for realizing these will be described below.

FIG. 2 is a schematic external view of the wind turbine generator according to the first embodiment of the present invention. In FIG. 2, a hatch 4 is provided below the nacelle 2 . A winch (not shown) is provided in the hatch 4, and a wire 6 is wound around the winch. By operating the winch, the wire 6 is withdrawn or wound up from the rotating drum of the winch. The wire 6 is positioned on the outer peripheral side of the tower 3. A defect detection device 5 is fixed to the wire 6 , and the defect detection device 5 is suspended from the nacelle 2 .

The defect detection device 5 is equipped with an infrared camera, and the defect detection device 5 fixed to the wire 6 moves up and down when the wire 6 is pulled out or wound up by a winch operation. Further, by rotating the nacelle 2, the defect detection device 5 moves in the circumferential direction around the outer periphery of the tower 3. FIG. The nacelle 2 and the wire 6 provided in this nacelle 2 constitute moving means for moving the defect detection device 5 .

A welded portion 7 is formed on the outer surface of the tower 3 along the circumferential direction. In addition, the tower 3 has portions where the tower members face each other and are fixed by fastening with bolts. If the welded portion 7 cracks or the bolt loosens, the bending moment due to the turning of the nacelle 2 changes, thereby changing the opening state. The defect detection device 5 detects defects from this change in the opening state. In the first embodiment, the welded portion 7 and the bolted portion are collectively referred to as a connecting portion.

When the nacelle 2 is rotated, the defect detection device 5 suspended and fixed to the wire 6 moves along the circumferential direction of the tower 3 and images the welded portion 7 and the bolted portion. When the nacelle 2 makes one turn around the tower 3, it is possible to image the entirety of the welded portion 7 and the bolted portion within a predetermined range. Repeat this several times. Since a plurality of welding parts 7 and bolt fastening parts are formed in the vertical direction of the tower 3, the wire 6 is pulled out and wound by operating the winch, and the defect detection device 5 fixed to the wire 6 is moved in the vertical direction. change the position of A plurality of wires 6 extending from the defect detection device 5 to the ground side are provided. The distance between the defect detection device 5 and the tower 3 is adjusted by holding the lower ends of these wires 6 on the ground side and adjusting the positions of the lower ends. Then, the infrared camera of the defect detection device 5 is maintained at a distance at which the defect can be imaged.

In the first embodiment, utilizing the fact that the center of gravity of the nacelle 2 holding the blades 1 is deviated from the central axis of the tower 3, the nacelle 2 is turned when a defect is detected, and the state of the bending moment applied to the tower 3 is actively measured. change to

Cracks may occur in the welded portion 7 due to changes in the bending moment applied to the tower 3, poor welding, and the like. Also, at the bolted portion, the bolt may become loose due to a change in the bending moment applied to the tower 3 or insufficient bolt tightening torque. Since the stress state around the defect changes relative to the compression side and the tension side due to changes in the bending moment, the opening state changes due to cracks at the welded portion 7 and loosening of the bolt at the bolted portion. The opening becomes a defect in the tower 3. The defect opening occurs on the tensile side. For this reason, the defect detection device 5 is positioned on the side opposite to the center of gravity with respect to the turning center TC.

The defect detection device 5 is moved in accordance with the turning motion of the nacelle 2, and inspects changes in the opening state of the connection portions (welded portions 7, bolt fastening portions). Then, the defect detection device 5 picks up an image of the opening generated by the turning of the nacelle 2 to detect the defect. The drive means for rotating the nacelle 2 functions as an opening changing means for changing the opening state of the connecting portion (welded portion 7, bolt fastening portion). A nacelle 2 as moving means and a wire 6 attached to the nacelle 2 move the defect detection device 5 in accordance with the operation of the aperture changing means. Since the temperature of the defective portion where the open state has changed due to the turning of the nacelle changes, the defect detection device 5 detects this temperature change to identify the defective portion.

According to the first embodiment, it is possible to provide an inspection apparatus and an inspection method for a wind power generator with relatively low operating costs and improved reliability.

A second embodiment of the present invention will now be described with reference to FIG. FIG. 3 is an external schematic view of a wind turbine generator according to a second embodiment of the present invention. The same reference numerals are assigned to the configurations common to the first embodiment, and detailed description thereof will be omitted.

The second embodiment differs from the first embodiment in that the lower end of the wire 6 on the ground side is fixed by the wire holding portion 8 .

A defect detection device 5 is fixed to a wire 6, and a plurality of wires 6 extending from the defect detection device 5 to the ground side are provided. In the first embodiment, the ground-side lower end of the wire 6 was in a free state. In the second embodiment, the ground side lower ends of the plurality of wires 6 are fixed to the wire holding portion 8 . Therefore, the plurality of wires 6 are stable, and the position of the defect detection device 5 can be easily adjusted.

When the nacelle 2 is turned, the wire 6, the defect detection device 5, and the wire holder 8 move following the nacelle 2. - 特許庁When the wire holding part 8 moves in the circumferential direction of the tower 3, the wire holding part 8 moves while maintaining a predetermined distance from the tower 3. Therefore, the predetermined distance is maintained between the defect detection device 5 and the tower 3. It moves in the circumferential direction of the tower 3 while maintaining it. Then, the defect detection device 5 images the welded portion 7 and the bolted portion of the tower 3 .

According to the second embodiment, in addition to the effects of the first embodiment, since the lower end of the wire 6 on the ground side is connected to the wire holding portion 8, the defect detection device 5 and the tower 10 are connected when the nacelle 2 turns. It is possible to move in the circumferential direction of the tower 3 while maintaining a predetermined distance between the tower 3 and the workability of detecting defective portions in the welded portions 7 and bolted portions.

A third embodiment of the present invention will now be described with reference to FIG. FIG. 4 is a schematic external view of a part of the wind turbine generator according to the third embodiment of the present invention. The same reference numerals are assigned to the configurations common to those of the first and second embodiments, and detailed description thereof will be omitted.

The third embodiment differs from the first and second embodiments in that the defect detector 5, the wire 6, and the winch 9 are positioned inside the tower 3. FIG.

In the third embodiment, a winch 9 is installed in the upper part inside the tower 3 or in the lower part of the nacelle 2 . The winch 9 may be permanent or temporary. A defect detection device 5 is connected to the wire 6 wound around the winch 9 . By operating the winch 9, the wire 6 is pulled out or wound up, and the defect detection device 5 moves up and down accordingly. A landing 10 is installed inside the tower 3 , and the lower end position of the wire 6 lowered from below the defect detection device 5 is adjusted at the landing 10 . By adjusting the lower end position of the wire 6 on the landing 10, the distance between the inner wall surface of the tower 3 and the defect detection device 5 is adjusted, and the entire inner peripheral surface of the tower 3 can be imaged.

In imaging with the defect detection device 5 , the nacelle 2 is rotated, and the defect detection device 5 is moved along the inner circumference of the tower 3 in accordance with the rotation of the nacelle 2 . The nacelle 2 and the wire 6 attached to the nacelle 2 constitute moving means for moving the defect detection device 5 .

The defect detection device 5 picks up an image of the opening state at the welded portion 7 and the bolt fastening portion by turning the nacelle to detect the defect. Since the temperature of the defective portion where the open state has changed due to the turning of the nacelle changes, the defect detection device 5 detects this temperature change to identify the defective portion.

Also, the tower 3 is formed by joining a plurality of cylindrical members by welding to form a tower member, stacking the plurality of tower members in the vertical direction, and fastening the flange fastening portions where the tower members face each other with bolts. The bolt may loosen due to repeated loads applied to the tower 3 . When the bolt loosens, an opening (gap) occurs at the bolted portion, similar to a crack.

In the third embodiment, the defect detection device 5 is moved in accordance with the turning of the nacelle 2, and the temperature change in the opening (gap) at the bolt fastening portion is detected by the defect detection device 5. FIG. In the third embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the third embodiment, in addition to the effects of the first and second embodiments, defects are detected by the defect detection device 5 inside the tower 3, thereby suppressing the effects of weather such as rain and wind. and the detection accuracy can be improved.

A fourth embodiment of the present invention will now be described with reference to FIG. FIG. 5 is an external schematic diagram of a wind turbine generator according to a fourth embodiment of the present invention. The same reference numerals are assigned to the configurations common to the first to third embodiments, and detailed description thereof will be omitted.

The fourth embodiment differs from the first to third embodiments in that the defect detection device 5 is mounted on the unmanned flying object 11 .

The unmanned air vehicle 11 is wirelessly operated and flies around (outside) the tower 3 . As the nacelle 2 turns, the unmanned flying object 11 flies around the outer circumference of the tower 3 , and the defect detection device 5 mounted on the unmanned flying object 11 images the welded portion 7 and the bolted portion of the tower 3 . The unmanned flying object 11 takes images of the welded portions 7 and bolted portions at multiple locations on the tower 3 by changing the altitude. The unmanned flying object 11 constitutes moving means for moving the defect detection device 5 .

Since the temperature of the defective portion where the open state is changed by the rotation of the nacelle 2 changes, the defect detection device 5 detects this temperature change to identify the defective portion.

In the fourth embodiment, the unmanned flying object 11 equipped with the defect detection device 5 is moved according to the turning of the nacelle 2, and the defect detection device 5 detects the temperature change in the gap between the welded portion 7 and the bolt fastening portion. In the fourth embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the fourth embodiment, since the unmanned flying object 11 equipped with the defect detection device 5 detects defects, the defect of the tower 3 can be detected without installing a special device in the wind turbine generator. Also, the workability of inspection can be improved.

A fifth embodiment of the present invention will now be described with reference to FIG. FIG. 6 is a schematic external view of a part of a wind turbine generator according to a fifth embodiment of the present invention. The same reference numerals are assigned to the configurations common to those of the first to fourth embodiments, and detailed description thereof will be omitted.

The fifth embodiment differs from the fourth embodiment in that an unmanned flying object 11 equipped with a defect detection device 5 is flown inside the tower 3 .

The unmanned air vehicle 11 is wirelessly operated and flies around the inner circumference of the tower 3 . As the nacelle 2 turns, the unmanned flying object 11 flies around the inner periphery of the tower 3, and the defect detection device 5 mounted on the unmanned flying object 11 images the welded portion 7 and the bolt fastening portion of the tower 3. The unmanned flying object 11 takes images of the welded portions 7 and bolted portions at multiple locations on the tower 3 by changing the altitude. The unmanned flying object 11 constitutes moving means for moving the defect detection device 5 .

Since the temperature of the defective portion where the open state is changed by the rotation of the nacelle 2 changes, the defect detection device 5 detects this temperature change to identify the defective portion.

In the fifth embodiment, the unmanned flying object 11 equipped with the defect detection device 5 is moved in accordance with the turning of the nacelle 2, and the defect detection device 5 detects the temperature change in the welded portion 7 and the opening (gap) at the bolt fastening portion. To detect. In the fifth embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the fifth embodiment, since the unmanned flying object 11 equipped with the defect detection device 5 detects defects, the defect of the tower 3 can be detected without installing a special device in the wind turbine generator. Also, the workability of inspection can be improved.

Furthermore, according to the fifth embodiment, since the unmanned flying object 11 equipped with the defect detection device 5 is designed to fly inside the tower 3, it is not affected by weather conditions such as rain and wind, and can fly stably. , the detection accuracy can be improved.

A sixth embodiment of the present invention will now be described with reference to FIG. FIG. 7 is an external schematic diagram of a wind turbine generator according to a sixth embodiment of the present invention. The same reference numerals are assigned to the configurations common to those of the first to fifth embodiments, and detailed description thereof will be omitted.

The sixth embodiment differs from the first to fifth embodiments in that the defect detection device 5 is mounted on the self-propelled robot 12 .

The self-propelled robot 12 is wirelessly operated and travels around (outside) the tower 3 . As the nacelle 2 turns, the self-propelled robot 12 travels around the tower 3 , and the defect detector 5 mounted on the self-propelled robot 12 images the welded portion 7 and the bolt fastening portion of the tower 3 . By changing the height position, the self-propelled robot 12 captures images of the welded portions 7 and bolted portions at multiple locations on the tower 3 . The self-propelled robot 12 constitutes moving means for moving the defect detection device 5 .

Since the temperature of the defective portion where the open state is changed by the rotation of the nacelle 2 changes, the defect detection device 5 detects this temperature change to identify the defective portion.

In the sixth embodiment, the self-propelled robot 12 equipped with the defect detection device 5 is moved according to the turning of the nacelle 2, and the defect detection device 5 detects the temperature change of the opening (gap) at the welded portion 7 and the bolt fastening portion. to detect In the sixth embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the sixth embodiment, since the defect is detected by the self-propelled robot 12 equipped with the defect detection device 5, the defect of the tower 3 can be detected without installing a special device in the wind turbine generator. It can be detected, and the workability of inspection can be improved.

A seventh embodiment of the present invention will now be described with reference to FIG. FIG. 8 is a partially transparent external schematic diagram of a wind turbine generator according to a seventh embodiment of the present invention. The same reference numerals are assigned to the configurations common to those of the first to sixth embodiments, and detailed description thereof will be omitted.

The seventh embodiment differs from the sixth embodiment in that a self-propelled robot 12 equipped with a defect detection device 5 is arranged inside the tower 3 .

The self-propelled robot 12 is wirelessly operated and travels around the inner circumference of the tower 3 . As the nacelle 2 turns, the self-propelled robot 12 travels along the inner periphery of the tower 3 , and the defect detector 5 mounted on the self-propelled robot 12 images the welded portion 7 and the bolt fastening portion of the tower 3 . By changing the height position, the self-propelled robot 12 captures images of the welded portions 7 and bolted portions at multiple locations on the tower 3 . The self-propelled robot 12 constitutes moving means for moving the defect detection device 5 .

Since the temperature of the defective portion where the open state is changed by the rotation of the nacelle 2 changes, the defect detection device 5 detects this temperature change to identify the defective portion.

In the seventh embodiment, the self-propelled robot 12 equipped with the defect detection device 5 is moved according to the turning of the nacelle 2, and the defect detection device 5 detects the temperature change in the gap between the welded part 7 and the bolt fastening part. . In the seventh embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the seventh embodiment, since the defect is detected by the self-propelled robot 12 equipped with the defect detection device 5, the defect of the tower 3 can be detected without installing a special device in the wind turbine generator. It can be detected, and the workability of inspection can be improved.

Furthermore, according to the seventh embodiment, since the self-propelled robot 12 equipped with the defect detection device 5 flies inside the tower 3, it is not affected by weather such as rain and wind, and can travel stably. It is possible to improve the detection accuracy.

Next, an eighth embodiment of the present invention will be described with reference to FIG. FIG. 9 is an external schematic diagram of a wind turbine generator according to an eighth embodiment of the present invention. The same reference numerals are assigned to the configurations common to those of the first to seventh embodiments, and detailed description thereof will be omitted.

The eighth embodiment differs from the first to seventh embodiments in that a scaffolding 13 for high-place work is built around the outer periphery of the tower 3, and the defect detection device 5 is operated manually. In the eighth embodiment, the scaffolding 13 is part of the outer periphery of the tower 3, but it is preferable to cover the entire outer periphery of the tower 3.

A worker 20 carries the defect detection device 5 and moves around the outer circumference of the tower 3 using the scaffolding 13 . As the nacelle 2 turns, the worker 20 moves along the outer periphery of the tower 3 and images the welded portion 7 and bolt fastening portion of the tower 3 with the defect detection device 5 . The operator 20 changes the height position using the scaffolding 13 to capture images of the welded portions 7 and bolted portions at multiple locations on the tower 3 . The scaffolding 13 constitutes moving means for moving the defect detection device 5 .

Since the temperature of the defective portion where the open state is changed by the rotation of the nacelle 2 changes, the defect detection device 5 detects this temperature change to identify the defective portion.

In the eighth embodiment, a worker 20 holding a defect detection device 5 moves as the nacelle 2 turns, and the defect detection device 5 detects temperature changes in gaps between the welded portion 7 and the bolt fastening portion. In the eighth embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the eighth embodiment, the operator 20 carrying the defect detection device 5 moves to detect defects. can be done. Further, according to the eighth embodiment, since the scaffolding 13 is assembled around the outer periphery of the tower 3, the defect can be repaired immediately after the defect is discovered.

Next, a ninth embodiment of the present invention will be described with reference to FIG. FIG. 10 is a partially transparent external schematic diagram of a wind turbine generator according to a ninth embodiment of the present invention. Configurations common to those of the first to eighth embodiments are denoted by the same reference numerals, and detailed description thereof will be omitted.

The ninth embodiment differs from the eighth embodiment in that a scaffolding 13 for high-place work is assembled inside the tower 3, and the defect detection device 5 is operated manually. In the eighth embodiment, scaffolding 13 is installed on landing 10 inside tower 3 .

A worker 20 holds the defect detection device 5 and moves around the inner circumference of the tower 3 using the scaffolding 13 . As the nacelle 2 turns, the worker 20 moves along the inner periphery of the tower 3 and images the welded portion 7 and bolt fastening portion of the tower 3 with the defect detection device 5 . The operator 20 changes the height position using the scaffolding 13 to capture images of the welded portions 7 and bolted portions at multiple locations on the tower 3 . The scaffolding 13 constitutes moving means for moving the defect detection device 5 .

Since the temperature of the defective portion where the open state is changed by the rotation of the nacelle 2 changes, the defect detection device 5 detects this temperature change to identify the defective portion.

In the ninth embodiment, the operator 20 with the defect detection device 5 moves as the nacelle 2 turns, and the defect detection device 5 detects the temperature change in the gap between the welded portion 7 and the bolt fastening portion. In the eighth embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the ninth embodiment, since the operator 20 carrying the defect detection device 5 moves to detect defects, it is possible to detect defects in the tower 3 according to the turning state of the nacelle 2. can be done. In addition, according to the eighth embodiment, since the scaffolding 13 is assembled on the inner periphery of the tower 3, it is not affected by weather such as rain and wind, and stable inspection can be performed, thereby improving the detection accuracy. can be done.

A tenth embodiment of the present invention will now be described with reference to FIG. FIG. 11 is a schematic external view of a wind turbine generator according to a tenth embodiment of the present invention. The same reference numerals are assigned to the configurations common to the first to ninth embodiments, and detailed description thereof will be omitted.

The tenth embodiment differs from the first to ninth embodiments in that an aerial work vehicle 14 is provided outside the tower 3 and the defect detection device 5 is manually operated.

A worker 20 holds the defect detection device 5, gets on the aerial work vehicle 14, and moves to a predetermined height position. As the nacelle 2 turns, the worker 20 moves along the outer periphery of the tower 3 and images the welded portion 7 and bolt fastening portion of the tower 3 with the defect detection device 5 . The operator 20 changes the height position of the aerial work vehicle 14 to capture images of the welded portions 7 and bolted portions at multiple locations on the tower 3 . The defect detection device 5 may be fixed to the aerial work vehicle 14 . The aerial work vehicle 14 constitutes moving means for moving the defect detection device 5 .

Since the temperature of the defective portion where the open state is changed by the rotation of the nacelle 2 changes, the defect detection device 5 detects this temperature change to identify the defective portion.

In the tenth embodiment, a worker 20 with a defect detection device 5 moves as the nacelle 2 turns, and the defect detection device 5 detects the temperature change in the gap between the welded portion 7 and the bolt fastening portion. Alternatively, the aerial work vehicle 14 to which the defect detection device 5 is fixed moves along with the turning of the nacelle 2, and the defect detection device 5 detects the temperature change in the gap between the welded portion 7 and the bolt fastening portion.

In the tenth embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the tenth embodiment, since the defect detection device 5 is moved by the aerial work vehicle 14 to detect defects, it is possible to detect defects in the tower 3 according to the turning state of the nacelle 2. .

Next, an eleventh embodiment of the present invention will be described with reference to FIG. FIG. 12 is a partially transparent external schematic diagram of a wind turbine generator according to an eleventh embodiment of the present invention. The same reference numerals are assigned to the configurations common to the first to tenth embodiments, and detailed description thereof will be omitted.

The eleventh embodiment differs from the tenth embodiment in that a ladder 15 is erected on a landing 10 inside the tower 3 and the defect detection device 5 is manually operated.

A worker 20 holds the defect detection device 5, climbs the ladder 15, and moves to a predetermined height position. As the nacelle 2 turns, the worker 20 moves the defect detection device 5 along the inner circumference of the tower 3 , and images the welded portion 7 and the bolt fastening portion of the tower 3 with the defect detection device 5 . By changing the height position of the ladder 15 , the operator 20 captures images of the welded portions 7 and bolted portions at multiple locations on the tower 3 . The ladder 15 constitutes moving means for moving the defect detection device 5 .

Since the temperature of the defective portion where the open state is changed by the rotation of the nacelle 2 changes, the defect detection device 5 detects this temperature change to identify the defective portion.

In the eleventh embodiment, the operator 20 moves the defect detection device 5 in accordance with the turning of the nacelle 2, and the defect detection device 5 detects the temperature change in the gap between the welded portion 7 and the bolt fastening portion. In the eleventh embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the eleventh embodiment, the operator 20 carrying the defect detection device 5 moves the defect detection device 5 to detect defects. Defects can be detected.

A twelfth embodiment of the present invention will now be described with reference to FIG. FIG. 13 is an external schematic diagram of a wind turbine generator according to a twelfth embodiment of the present invention. The same reference numerals are assigned to the configurations common to those of the first to eleventh embodiments, and detailed description thereof will be omitted.

The twelfth embodiment differs from the first to eleventh embodiments in that a gondola 16 is arranged around the tower 3 so that the defect detection device 5 is manually operated.

The gondola 16 is suspended by wires 19 extending from below the nacelle 2 . A winch (not shown) is provided inside the nacelle 2 . A worker 20 rides on the gondola 16 with the defect detection device 5 and operates the winch to move the gondola 16 connected to the wire 19 to a predetermined height position. The defect detection device 5 may be fixed to the gondola 16 . As the nacelle 2 turns, the operator 20 moves the defect detection device 5 along the outer circumference of the tower 3 , and images the welded portion 7 and the bolt fastening portion of the tower 3 with the defect detection device 5 . By changing the height position of the gondola 16 , the operator 20 captures images of the welded portions 7 and bolted portions at a plurality of locations on the tower 3 . The nacelle 2 , the wire 19 and the gondola 16 constitute moving means for moving the defect detection device 5 .

Since the temperature of the defective portion where the open state is changed by the rotation of the nacelle 2 changes, the defect detection device 5 detects this temperature change to identify the defective portion.

In the twelfth embodiment, the operator 20 moves the defect detection device 5 as the nacelle 2 turns, and the defect detection device 5 detects the temperature change in the gap between the welded portion 7 and the bolted portion. In the twelfth embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the twelfth embodiment, the defect detection device 5 is moved by the gondola 16 for defect detection, so that the defect of the tower 3 can be detected according to the turning state of the nacelle 2 .

A thirteenth embodiment of the present invention will now be described with reference to FIG. FIG. 14 is an external schematic view of a tower of a wind turbine generator according to a thirteenth embodiment of the present invention. The same reference numerals are assigned to the configurations common to those of the first to twelfth embodiments, and detailed description thereof will be omitted.

The thirteenth embodiment differs from the first to twelfth embodiments in that the defect detection device 5 is mounted on the unmanned aircraft 11, and the openings of the welded portions 7 and the bolt fastening portions on the outer surface of the tower 3 before and after the nacelle 2 is mounted. The reason is that the state change is inspected.

The unmanned flying object 11 is wirelessly operated and flies around the tower 3 , and the defect detection device 5 mounted on the unmanned flying object 11 images the welded part 7 and the bolt fastening part of the tower 3 . The unmanned flying object 11 takes images of the welded portions 7 and bolted portions at multiple locations on the tower 3 by changing the altitude. The unmanned flying object 11 constitutes moving means for moving the defect detection device 5 .

First, before mounting the nacelle 2 , the unmanned flying object 11 flies around the outer periphery of the tower 3 , the defect detection device 5 mounted on the unmanned flying object 11 images the welded part 7 and the bolt fastening part of the tower 3 , and Inspect changes in surface opening conditions.

Next, after mounting the nacelle 2 , the unmanned flying object 11 flies around the outer periphery of the tower 3 , and the defect detection device 5 mounted on the unmanned flying object 11 images the welding part 7 and the bolt fastening part of the tower 3 . Inspect changes in the open state of the outer surface.

Then, the temperature changes before and after the nacelle 2 is mounted are compared. Poor welding in the welded portion 7 and insufficient tightening of bolts in the bolted portion are defective portions. Detect changes and identify defect locations.

In the thirteenth embodiment, the unmanned flying object 11 equipped with the defect detection device 5 is moved along the outer periphery of the tower 3, and the defect detection device 5 detects the temperature change in the opening (gap) at the welded portion 7 and the bolt fastening portion. To detect. In the thirteenth embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the thirteenth embodiment, defects are detected by the unmanned flying object 11 on which the defect detection device 5 is mounted, so defects in the tower 3 under construction can be detected.

A fourteenth embodiment of the present invention will now be described with reference to FIG. FIG. 15 is a schematic external view of the tower of the wind turbine generator according to the fourteenth embodiment of the present invention. Configurations common to those of the first to thirteenth embodiments are denoted by the same reference numerals, and detailed description thereof will be omitted.

The 14th embodiment differs from the 1st to 13th embodiments in that the defect detection device 5 is mounted on the self-propelled robot 12, and the welding part 7 and the bolt fastening part on the outer surface of the tower 3 before and after the nacelle 2 is mounted. The reason is that the change in the opening state is inspected.

The self-propelled robot 12 is wirelessly operated and travels around the tower 3 , and the defect detector 5 mounted on the self-propelled robot 12 picks up images of the welded parts 7 and bolt fastening parts of the tower 3 . By changing the height position, the self-propelled robot 12 captures images of the welded portions 7 and bolted portions at multiple locations on the tower 3 . The self-propelled robot 12 constitutes moving means for moving the defect detection device 5 .

First, before the nacelle 2 is mounted, the self-propelled robot 12 travels around the outer circumference of the tower 3, and the defect detection device 5 mounted on the self-propelled robot 12 images the welded part 7 and the bolt fastening part of the tower 3. 3 Inspect changes in the open state of the outer surface.

Next, after mounting the nacelle 2, the self-propelled robot 12 runs around the outer circumference of the tower 3, and the defect detection device 5 mounted on the self-propelled robot 12 images the welded part 7 and the bolt fastening part of the tower 3, A change in the opening state of the outer surface of the tower 3 is inspected.

Then, the temperature changes before and after the nacelle 2 is mounted are compared. Poor welding in the welded portion 7 and insufficient tightening of bolts in the bolted portion are defective portions. Detect changes and identify defect locations.

In the 14th embodiment, the self-propelled robot 12 equipped with the defect detection device 5 is moved along the outer periphery of the tower 3, and the defect detection device 5 detects the temperature change of the opening (gap) at the welded portion 7 and the bolt fastening portion. to detect In the thirteenth embodiment, by detecting this temperature change, it is possible to detect defects in the welded portion 7 and the bolted portion.

According to the fourteenth embodiment, since the unmanned flying object 11 equipped with the defect detection device 5 detects defects, it is possible to detect defects in the tower 3 under construction.

A fifteenth embodiment of the present invention will now be described with reference to FIG. FIG. 16 is a schematic external view of a wind turbine generator according to a fifteenth embodiment of the present invention. The same reference numerals are assigned to the configurations common to the first to fourteenth embodiments, and detailed description thereof will be omitted.

The fifteenth embodiment is different from the first to fourteenth embodiments in that the defect detecting device 5 is equipped with an indicating means 18 such as a paint gun, and the indicating means 18 specifies the defect detection position 17. be.

As in the first embodiment, the defect detector 5 is suspended from the nacelle 2 by a wire 6. FIG. The defect detection device 5 moves in the circumferential direction along the outer periphery of the tower 3 as the nacelle 2 turns, and images the welded portion 7 and the bolted portion. The nacelle 2 and the wire 6 constitute moving means for moving the defect detection device 5 .

When the defect detector 5 detects a defect in the welded portion 7 or the bolted portion, a mark is required to identify the defective portion. Therefore, in the fifteenth embodiment, the defect detecting device 5 is equipped with the indicating means 18 such as a paint gun.

As the nacelle 2 turns, the defect detection device 5 moves along the outer periphery of the tower 3. When the defect detection device 5 detects a defect in the welded portion 7 or the bolted portion, the operator operates the indicating means 18 to Apply ink to the defect. Then, the operator uses the applied ink as a mark to repair the defective portion.

According to the fifteenth embodiment, since the defect detection device 5 is equipped with the indicating means 18 such as a paint gun, it is possible to easily grasp the location of the detected defect.

Next, a 16th embodiment of the present invention will be described with reference to FIG. FIG. 17 is a schematic external view of a wind turbine generator according to a sixteenth embodiment of the present invention. The same reference numerals are assigned to the configurations common to those of the first to fifteenth embodiments, and detailed description thereof will be omitted.

The sixteenth embodiment differs from the fifteenth embodiment in that the unmanned flying object 11 is equipped with a defect detection device 5 and an indicating means 18 .

As in the fourth embodiment, the unmanned flying object 11 equipped with the defect detection device 5 is wirelessly operated and flies around the tower 3 . As the nacelle 2 turns, the unmanned flying object 11 flies around the outer circumference of the tower 3 , and the defect detection device 5 mounted on the unmanned flying object 11 images the welded portion 7 and the bolted portion of the tower 3 . The unmanned flying object 11 constitutes moving means for moving the defect detection device 5 .

As the nacelle 2 turns, the unmanned flying object 11 equipped with the defect detection device 5 moves around the outer periphery of the tower 3. By operating the means 18 , ink is applied to the defective portion of the tower 3 . Then, the operator uses the applied ink as a mark to repair the defective portion. The specifying means 18 has a function of specifying the defect detection position.

According to the 16th embodiment, since the unmanned flying object 11 is equipped with the indicating means 18 such as a paint gun, it is possible to easily grasp the detected defective portion.

A seventeenth embodiment of the present invention will now be described with reference to FIG. FIG. 18 is a schematic external view of a wind turbine generator according to the seventeenth embodiment of the present invention. The same reference numerals are assigned to the configurations common to those of the first to sixteenth embodiments, and detailed description thereof will be omitted.

The seventeenth embodiment differs from the fifteenth and sixteenth embodiments in that the self-propelled robot 12 is equipped with the defect detection device 5 and the indicating means 18 .

As in the sixth embodiment, the self-propelled robot 12 equipped with the defect detection device 5 is wirelessly operated to move around the tower 3 . As the nacelle 2 turns, the self-propelled robot 12 moves around the outer circumference of the tower 3, and the defect detection device 5 mounted on the self-propelled robot 12 takes images of the welded part 7 and the bolt fastening part of the tower 3. The self-propelled robot 12 constitutes moving means for moving the defect detection device 5 .

As the nacelle 2 turns, the self-propelled robot 12 equipped with the defect detection device 5 moves around the outer periphery of the tower 3. When the defect detection device 5 detects defects in the welded portion 7 and the bolted portion, the operator must The indicating means 18 is operated to apply ink to the defective portion of the tower 3 . Then, the operator uses the applied ink as a mark to repair the defective portion. The specifying means 18 has a function of specifying the defect detection position.

According to the 16th embodiment, since the self-propelled robot 12 is equipped with the indicating means 18 such as a paint gun, it is possible to easily grasp the detected defective portion.

As described above, according to each of the embodiments of the present invention, it is possible to provide an inspection apparatus for a wind power generator that suppresses an increase in operating costs and improves reliability.

In addition, the present invention is not limited to the above-described embodiments, and includes various modifications. The above-described embodiments have been described in detail for easy understanding of the present invention, and are not necessarily limited to those having all the described configurations.

DESCRIPTION OF SYMBOLS 1... Blade, 2... Nacelle, 3... Tower, 4... Hatch, 5... Defect detection apparatus, 6... Wire, 7... Welding part, 8... Wire holding part, 9... Winch, 10... Landing, 11... Unmanned flying object , 12... Self-propelled robot, 13... Scaffolding, 14... Aerial work vehicle, 15... Ladder, 16... Gondola, 17... Defect detection position, 18... Explicit means, 19... Wire, 20... Worker, 21... Spindle , 22... gearbox, 23... generator

Claims (14)

A blade that rotates in response to the wind,
a nacelle supporting the weight of the blade;
a tower configured by connecting a plurality of members and rotatably supporting the nacelle;
a defect detection device for detecting defects in the connecting portion of the tower;
a moving means for moving the defect detection device;
and driving means for turning the nacelle ,
the moving means moves the defect detection device in accordance with the turning motion of the driving means ;
The inspection apparatus for a wind turbine generator, wherein the defect detection device detects the defect based on an open state at the connecting portion of the tower . In claim 1,
An inspection device for a wind power generator, wherein the defect detection device includes an infrared camera. In claim 1,
An inspection apparatus for a wind power generator, wherein the connecting portion is a welded portion and a bolted portion. In claim 1 or 2 ,
The moving means is composed of the nacelle and a wire provided in the nacelle,
An inspection apparatus for a wind power generator, wherein the defect detection device is fixed to the wire. In claim 4 ,
The nacelle is equipped with a winch for pulling out or winding the wire,
An inspection device for a wind power generator, wherein the position of the defect detection device in the vertical direction is changed by operating the winch. In claim 4 ,
An inspection apparatus for a wind turbine generator, wherein a plurality of said wires extending from said defect detection device to the ground side are provided, and ground-side lower ends of said plurality of wires are fixed by a wire holding member. In claim 5 ,
An inspection apparatus for a wind power generator, wherein the winch is arranged inside the tower. In claim 1 or 2 ,
The moving means is composed of an unmanned flying object that flies outside or inside the tower,
An inspection device for a wind power generator, wherein the defect detection device is mounted on the unmanned flying object. In claim 1 or 2 ,
The moving means is composed of a self-propelled robot that runs outside or inside the tower,
An inspection apparatus for a wind power generator, wherein the defect detection device is mounted on the self-propelled robot. In claim 1 or 2 ,
The moving means is composed of an aerial work vehicle,
An inspection apparatus for a wind power generator, wherein the defect detection apparatus is mounted on the aerial work vehicle. In claim 1 or 2 ,
The moving means is composed of the nacelle, a wire provided in the nacelle, and a gondola connected to the wire,
An inspection device for a wind power generator, wherein the defect detection device is fixed to the gondola. In claim 1 or 2 ,
An inspection apparatus for a wind power generator, wherein the moving means includes a specifying means for specifying a defect detection position. A blade that rotates in response to the wind,
a nacelle supporting the weight of the blade;
a tower configured by connecting a plurality of members and rotatably supporting the nacelle;
a defect detection device for detecting defects in the connecting portion of the tower;
and a moving means for moving the defect detection device,
The inspection apparatus for a wind turbine generator, wherein the defect detection device detects the defect from a change in the opening of the connecting portion before and after the nacelle is mounted on the tower. A blade that rotates in response to the wind,
a nacelle supporting the weight of the blade;
a tower configured by connecting a plurality of members and rotatably supporting the nacelle;
A defect detection device that detects defects in the connecting portion of the tower, and a wind power generator inspection method comprising:
A method for inspecting a wind power generator, wherein the defect detection device is moved in accordance with the turning motion of the nacelle and detects the defect from a change in the opening state of the connecting portion.

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