JPH0574304B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Application of the Invention] The present invention relates to a wedge joint position changing method for reducing fretting fatigue occurring in a rotor core at the contact surface end of a rotor wedge in a rotating electric machine.

[Background of the invention]

In the rotor of a rotating electrical machine such as a turbine generator, fretting fatigue accumulates in the rotor core due to the sliding movement of the wedge inserted into the slot and the slot inner wall, which eventually causes fatigue cracks to easily occur. be. Regarding the occurrence of this fretting fatigue and measures to reduce it,
As disclosed in Publication No. 135647, local accumulation of fatigue is unavoidable.

[Purpose of the invention]

An object of the present invention is to provide a direction for changing the joint position of a rotor wedge in a rotating electric machine that can avoid local accumulation of fretting fatigue and prevent the occurrence of fatigue cracks.

[Summary of the invention]

In order to achieve this object, the present invention provides a rotor for a rotating electric machine having a plurality of wedges arranged in the axial direction for one slot, in which the length of the wedge at one end of the slot is set to the length of the wedge at the other end. Alternatively, the lengths of the wedges at both ends of the slot may be different and the lengths of the wedges at both ends of the slot may be different and the wedge at one end may be replaced with the other end. The lengths of the wedges are different, and the wedges at both ends can be arranged interchangeably, or by replacing them with other wedges whose lengths are equal in sum and their ratios are different. The wedge joint position of the rotor is changed to disperse the accumulation of fretting fatigue that occurs in the rotor core at the edge of the wedge contact surface, thereby preventing excessive fatigue accumulation from occurring locally. .

[Embodiments of the invention]

Hereinafter, one embodiment of the present invention will be described with reference to the drawings.

As shown in FIGS. 2 to 4, the rotor of a turbine generator has a slot 2 extending in the axial direction on the outer circumference of a rotor core 1, and a coil 3 housed in the slot 2 is placed on the outside of the rotor. This is a configuration in which an insulating block 4 and wedges 5a, 5b, . . . are inserted. The wedges 5a, 5b... are used to prevent the coil 3 from flying out due to the centrifugal force generated by the rotation of the rotor, and are dovetail shaped in this embodiment.
There are T-shapes, Christmas tree shapes, etc.

As this rotor rotates, the coil 3,
The centrifugal force generated in the insulating block 4 and the wedges 5a, 5b, . . . is received by the contact surface 6 between the rotor core 1 (inner wall surface of the slot) and the wedges 5a, 5b, . Moreover, the contact pressure on the contact surface 6 is concentrated at the end of each wedge 5a, 5b, . . ., near the joint 7 of the wedges 5a, 5b, .

On the other hand, if a long rotor of this type is placed in a machine and its both ends are supported by bearings, the rotor will bend due to its own weight using the bearings as a fulcrum as shown in FIG. In Fig. 5, 8 and 9 are the bearings, r is the radius of curvature of the rotor's deflection, r ₀ is the radius of the rotor, L is the length of the wedges 5a, 5b, etc., and l ₀ is the rotor. are straight, the wedges 5a, 5b...
l1 is the length of the wedge storage area when the wedge storage area is stored in the slot, _l1 is the length of the wedge storage area that is contracted by the bending of the rotor, and _l2 is the length of the wedge storage area that is expanded by the bending of the rotor. The length dimension of the wedge storage area, δ, is the amount of expansion and contraction of the wedge storage area.

When the rotor is in this state while rotating, the length of each wedge storage area in each slot 2 expands and contracts within the range of l ₁ to _{l 2} (=l ₀ ±δ). On the other hand, the changes in the length dimensions of the wedges 5a, 5b... are so small that they can be ignored. A ±δ slip occurs on the contact surface 6, and fretting fatigue occurs in this portion.

By the way, in this embodiment, the wedges 5a, 5b, . . . in each slot have _a reference dimension L ₀ as shown in _FIG . ₁ ≠L ₂ ) wedge 5a,
5b and a longer dimension at the other end.
L ₃ wedge 5g is placed.

When a certain degree of fretting fatigue is accumulated in the rotor core 1 at the wedge joint position due to the rotation of the rotor, the left end wedge 5a
The joint positions of the wedges 5a, 5b, . As a result, the fretting fatigue accumulation position in the rotor core 1 changes, so that fretting fatigue accumulation at the initial wedge joint position is stopped. When a certain degree of fretting fatigue is accumulated at the new wedge joint position resulting from this rearrangement of the wedges, the left end wedge 5b is removed and inserted from the right side of the right end wedge 5a to change the wedge joint position again.

By doing this, the fretting fatigue accumulation position with respect to the rotor core 1 is sequentially changed, so that
Fretting fatigue is not excessively accumulated at a particular wedge joint position, and therefore fatigue failure is prevented over a long period of time.

Note that various modifications can be made to this wedge replacement method. Some examples are explained below.

(a) Separately prepare wedges whose ends are equal to the sum of the lengths of the wedges and whose ratios are different, and replace them.

(b) Using a wedge whose ratio is equal to the sum of the lengths of the wedges at both ends and which differs from each other in another slot,
Replace these wedges with those in other slots.

(c) Replace the wedge at one end of each slot with the wedge at the other end.

Further, the shape of the wedge is not limited to one in which the entire surface of the wedge contacts the inner wall surface of the slot, but a similar function and effect can be obtained even if a portion of the wedge is in contact with the inner wall surface of the slot.

〔Effect of the invention〕

As described above, according to the present invention, the length of the wedge at one end of the slot is made different from the length of the other wedge, and the wedge at one end can be replaced with the other end, or Alternatively, the lengths of the wedges at both ends of the slot are made different from each other and the lengths of other wedges, and the wedges at both ends are arranged interchangeably.
Since the wedge joint position in the slot is changed by replacing the wedge with another wedge that has the same sum of lengths and a different ratio, it is possible to prevent excessive fretting fatigue from accumulating in the rotor core at a specific wedge joint position. It can be prevented.

[Brief explanation of the drawing]

The drawings show one embodiment of the present invention, and FIGS. 1A and 1B are explanatory views of the wedge arrangement, FIG. 2 is an external perspective view of the rotor, FIG. 3 is a vertical cross-sectional end view thereof, and FIG. FIG. 5, which is a partially enlarged perspective view, is a diagram illustrating the occurrence of fretting fatigue. 1... Rotor core, 2... Slot, 3... Coil, 5a to 5g... Wedge, 6... Contact surface,
7...Wedge seam.

Claims (1)

[Claims] 1. A plurality of slots formed in the rotor core;
A rotating electrical machine comprising a coil housed in these slots and a plurality of wedges inserted into the slots on the outer circumferential side of the coils and arranged in the axial direction to hold the coils in the slots. In the rotor, the length of the wedge at one end of the slot is made different from the length of the other wedge, and the wedge at one end is replaced with the other end to change the wedge joint position. A method for changing the joint position of a rotor wedge in a rotating electric machine, characterized in that: 2. According to claim 1, a plurality of wedges of different lengths are arranged at one end of the slot, and the wedge joint is formed by sequentially replacing the wedge at the other end starting with the wedge at the farthest end. A method for changing the joint position of a rotor wedge in a rotating electric machine, which is characterized by changing the position. 3 A plurality of slots formed in the rotor core,
A rotating electric machine comprising a coil housed in these slots and a plurality of wedges inserted into the slots on the outer circumferential side of the coils and arranged in the axial direction to hold the coils in the slots. In the rotor shown in FIG. A method for changing the joint position of a rotor wedge in a rotating electric machine, which is characterized by changing the position. 4 A plurality of slots formed in the rotor core,
A rotating electrical machine comprising a coil housed in these slots and a plurality of wedges inserted into the slots on the outer circumferential side of the coils and arranged in the axial direction to hold the coils in the slots. In the rotor, the lengths of the wedges at both ends of the slot are made different from each other and the lengths of the other wedges, and the wedges at both ends have the same length,
1. A method for changing the joint position of a rotor wedge in a rotating electric machine, characterized in that the wedge joint position is changed by replacing the wedge with another wedge having a different ratio. 5. Claim 4 provides a rotor wedge in a rotating electric machine, characterized in that wedges at both ends of other slots are used as other wedges having the same sum of lengths and different ratios. How to change the seam position.