JP2000217301A - Rotating machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rotating machine which facilitates its attaching to the stator and improves its damping capacity of mechanical vibrations. SOLUTION: This rotating machine (turbine generator) 1 is provided with a stator upper frame 5 covering the upper part of a stator 2, a stator frame body 4 with a stator lower frame 6 covering the lower of the stator 2, an elastic support body 71, a lower support body 72, a support mechanism 7 with a reinforcing body 73, and a cooler 8 disposed on the stator lower frame 6 in contrast to a conventional example one. The height dimension H from the top surface of a base 9 of the stator 2 is higher than that of the conventional example, and the position of the commissure 4a of stator upper frame 5 and the stator lower frame 6 is set so as to become lower than the height dimension H by a dimension ΔH. The elastic support body 71 is set so that the interval length L of the center position of a weld to the outer surface side of the stator 2 and the central position of the side end welded by the lower support body 72 may become longer than that of the conventional example, and the reinforcing body 73 has a vertically split cylindrical shape in its cross-section, and the end part thereof is welded to the side surface of the lower support body 72 as well as the side end of the elastic support body 71.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotating electric machine having a support mechanism for suppressing transmission of mechanical vibration caused by a vibration component generated in a device to a foundation, and mounting the support mechanism on a stator. And a structure for improving the damping ability against mechanical vibration.

[0002]

2. Description of the Related Art A large-capacity rotary electric machine such as a turbine generator generally has a support mechanism capable of suppressing a transmission amount of mechanical vibration caused by an electromagnetic force generated in a device to a foundation. A conventional rotary electric machine having such a support mechanism will be described below as a typical example of a turbine generator. This turbine generator uses a cylindrical stator arranged such that the central axis is horizontal, a cylindrical rotor combined inside the stator, and a refrigerant gas using the stator and the rotor. A cooling device, a stator frame, and a support mechanism for elastically supporting the stator are generally provided, and are mounted on a foundation with the stator frame.

[0003] The stator frame has a stator upper frame that covers the upper part of the stator, and a stator lower frame that covers the lower part of the stator and is installed on the foundation. Are joined by the lower edge of the stator upper frame and the upper edge of the stator lower frame to form an integral frame that covers the stator from the outside. The joint between the lower edge of the stator upper frame and the upper edge of the stator lower frame is set at a position equivalent to the height of the center axis of the stator. The support mechanism mainly includes a plurality of elastic supports, and the elastic supports are formed in a flat plate shape having an inverted T-shaped surface shape. Each of the elastic supports is attached to the outer surface side portion at the height of the center axis of the stator at the upper portion by a welding method, and is disposed in such a posture that the flat plate surface is substantially at a vertical position, The lower part of the lower frame is fixed to the side surface of the flat member of the stator lower frame by a welding method to elastically support the stator.

[0004] The cooler is mounted on the stator upper frame. Since the lower stator frame supports the weight of the stator, stator upper frame, and cooler, it must have high rigidity.
For this purpose, it is desirable to make the height dimension of the stator lower frame as large as possible. It is for this reason that the position of the upper edge of the stator lower frame is set at a position equivalent to the height of the center axis of the stator. The main role of the elastic support is to reduce the amount of mechanical vibration generated when the stator is pulled by the main magnetic flux to the foundation, and to control the short-circuit torque generated by the stator when the turbine generator suddenly short-circuits. It is sure support.

The mechanical vibration force generated on the stator by the main magnetic flux has a vibration mode that deforms the stator into an elliptical shape in the case of a two-pole turbine generator. The elastic support has a shape and structure acting as a spring body, and plays a role of reducing the amount of transmission of the mechanical vibration to the foundation by a well-known vibration damping action of the spring body. In addition, when supporting the short-circuit torque, the elastic support needs to minimize the generation of bending stress in the elastic support due to the short-circuit torque. Therefore, it is desirable to receive the force due to the short-circuit torque in the vertical direction. The structure of the support mechanism described above is adapted to this.

[0006]

Since the above-described conventional turbine generator is constructed as described above,
The support mechanism suppresses the transmission of mechanical vibration to the foundation and reliably supports the short-circuit torque generated at the time of sudden short-circuit. However, the following problems have emerged as problems. That is, (a) From the above description, it is desirable that the elastic support is attached to the outer surface side of the stator at the height of the center axis of the stator, and the stator lower frame has a large rigidity. For this reason, the position of the upper edge is set to a position equivalent to the height of the center axis of the stator. For this reason, it is difficult to attach the elastic support to the stator by the welding method, and the number of operation steps is increased, resulting in a problem that the manufacturing cost is expensive. (B) By increasing the mechanical vibration damping capability of the elastic support, it is possible to increase the mechanical vibration force generated on the stator by the main magnetic flux, and to design and manufacture the stator and rotor. It is known that such conditions can be relaxed. However, increasing the vibration damping capacity of the elastic support as a spring body reduces the spring constant in a direction perpendicular to the plate surface of the elastic support (horizontal in the case of the above-described conventional turbine generator). This requires an increase in the length of the elastic support. This has reached the limit from what has been described in the above (a). Therefore, it is difficult to reduce the manufacturing cost of the mechanical vibration force generated by the main magnetic flux by relaxing conditions such as design and manufacture of the stator and the rotor. Furthermore, (c) the elastic support is desirably disposed so that the plate surface thereof is at the vertical position as described above. However, in order to allow manufacturing errors, the elastic support is slightly moved from the vertical position. It is a fact that they are staggered. If the arrangement posture of the elastic support is shifted from the vertical position, when short-circuit torque is generated, bending stress is generated in the elastic support in accordance with the shift (shift angle) from the vertical position. Due to this bending stress, a torsional torque is applied to the fixed portion between the elastic support and the plate-shaped member of the stator lower frame, and when the fixed portion is constructed by a welding method, this welding is performed. A large local stress acts on the part. Thus, of course, there is an acceptable limit on the local stress, and there is also an acceptable limit on the offset angle. The allowable deviation angle becomes smaller as the length of the elastic support is longer, from the allowable local stress. That is, the allowable deviation angle regarding the disposition posture of the elastic support is also a constraint condition for increasing the length of the elastic support as in the case of the above item (b).

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems of the prior art, and has as its object to provide a stator support mechanism, which facilitates attachment to the stator and improves damping ability against mechanical vibration. An object of the present invention is to provide a rotating electric machine aiming at the above.

[0008]

According to the present invention, there are provided the following objects: 1) a stator, a rotor combined with the stator, a cooler for cooling the stator and the rotor, and an upper portion of the stator. A rotation provided with a stator frame having a stator upper frame to be covered, a stator lower frame covering the lower portion of the stator and being installed on a foundation, and a support mechanism for elastically supporting the stator on the stator lower frame. In an electric machine, a stator frame is formed as an integral frame by combining a stator upper frame and a stator lower frame with a lower edge of the stator upper frame and an upper edge of the stator lower frame. The support mechanism has an inverted T-shaped surface shape and is fixed to the side of the outer surface of the stator at the upper part,
A flat elastic support for elastically supporting the stator; a flat elastic support disposed below the stator and fixed to the stator lower frame;
A flat lower support that fixes the side of the elastic support on the side surface, and a portion where the elastic support is fixed to the side of the outer surface of the stator is above the upper edge of the stator lower frame As described above, the position of the upper edge of the stator lower frame is set, or 2) In the means described in the above item 1, the cooler is accommodated in the stator frame and fixed. (3) In the means described in the above (1) or (2), the support mechanism is provided on a side surface of the elastic support at a portion fixed to the lower support. This is achieved by providing a structure having a reinforcing body having a cross-sectional shape like a half-cut cylindrical body.

[0009]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a partially cutaway BB and CC cutaway view in FIG. 2 showing the outline of a rotary electric machine according to an example of an embodiment of the present invention. FIG. 2 is a sectional view taken along line AA of FIG. 1, and FIG. 3 is a sectional view taken on line D-A of FIG.
It is D sectional drawing. In addition, in FIG.
2 shows a BB section, and shows a partially broken CC section in FIG. 2 except for the rotor. The dashed line in FIG. 1 is the vertical plane ZZ, and the dashed line in FIG.
It is the central axis XX.

1 to 3, reference numeral 1 denotes a stator 2;
It is a horizontal axis-type turbine generator including a rotor 3, a stator frame 4, a support mechanism 7, and three coolers 8, and is installed on a foundation 9. In the turbine generator 1 according to the present invention, the height H of the center axis XX of the stator 2 from the upper surface of the foundation 9 is set higher than in the conventional example,
The arrangement of the cooler 8 below the stator 2 is significantly different from the conventional example.

The stator 2 is configured so that the central axis XX is in the horizontal direction, and has a cylindrical stator core having a laminated structure using a stator core plate made of a thin plate, and a stator core. A stator winding composed of a plurality of stator coils loaded in each of the coil slots formed in the coil slot, an annular press ring disposed at both ends of the stator core and pressing the stator core plate in the laminating direction, A plurality of stator core mounting beams into which grooves formed in the outer peripheral portion of the stator core plate are respectively fitted, and three annular support rings 21 for joining all the stator core mounting beams from the outer peripheral side. , Each support ring 21
Ring seats 22 and 22 fixed by welding to the vicinity of the center axis XX position on the outer peripheral surface of the pair of members (L) mounted on a support mechanism mounting portion 221 formed on each ring seat 22 (Having a U-shaped surface shape). In addition, the support mechanism mounting portion 22
The center position in the height direction of the turbine generator 1 is
It almost coincides with the position of the central axis line XX.

The rotor 3 includes a rotor core portion having a circular outer peripheral surface disposed through a gap between the circular inner peripheral surface of the stator core and a coil, and a coil formed on the outer peripheral surface of the rotor core portion. A rotor winding composed of a plurality of saddle coils loaded in each of the slots, a cylindrical holder covering each of both ends of the rotor winding, a rotor core formed integrally with the rotor core; A rotating shaft portion having a circular outer diameter concentric with the portion, an axial flow fan (not shown) mounted on the rotating shaft portion at a portion adjacent to the holder, and rotatably supported via a bearing (not shown). I have. Since the structures of the stator 2 and the rotor 3 are basically the same as those of the conventional turbine generator, detailed description thereof will be omitted.

The stator frame 4 has a stator upper frame 5 that covers the upper portion of the stator 2 and a stator lower frame 6 that covers the lower portion of the stator 2 and is installed on the foundation 9. The lower edge of the lower frame 5 and the upper edge of the stator lower frame 6 are combined to form an integral frame. In the stator frame 4, the joint 4 a between the lower edge and the upper edge, that is, the height position of the upper edge of the stator lower frame 6 is lower than the height H by the dimension ΔH. H
Set to ₆ . Setting the height position of the upper edge of the stator lower frame 6 lower than the height dimension H by the dimension ΔH is as follows.
This is one of the features of the turbine generator 1.

The structure of the stator upper frame 5 is simplified by not mounting the cooler 8 in comparison with the conventional example.
It has an outer cover 51 and partition plates 52, 52 inside the outer cover 51, which are in contact with the end of the stator 2 and partition a flow path of a not-shown refrigerant gas (for example, air). Stator lower frame 6
Has a jacket 61, leg plates 62, 62, and a bottom plate 63, and is installed on the foundation 9 with the leg plates 62, 62. In the stator lower frame 6, three coolers 8 are mounted on the jacket 61 and arranged below the stator 2. This is also one of the features of the turbine generator 1. One. The cooler 8 has a role of cooling the stator 2 and the rotor 3 via the refrigerant gas. The cooling structure of the cooler 8 is the same as that of the conventional cooler of the turbine generator. Since the structure is equivalent to that of the structure, the detailed description of the cooler 8 is omitted.

In the stator frame 4, the cooler 8 is mounted on the stator lower frame 6 differently from the conventional example, so that no wasteful space is created and the stator 2 is cooled. The height dimension H can be made higher than in the conventional example. Also, by attaching the cooler 8 to the stator lower frame 6,
The weight of the cooler 8 is prevented from being added to the stator lower frame 6 from above, and the weight of the stator upper frame 5 whose configuration is simplified by not mounting the cooler 8 is greater than that of the conventional example. A favorable condition can be created for the configuration of the stator lower frame 6, which is reduced. As a result, the rigidity of the lower stator frame 6 can be reduced as compared with the conventional example, and the upper edge of the lower stator frame 6 can be easily moved to a position lower by the dimension ΔH than the height dimension H. Can be set.

In this case, the support mechanism 7 has six flat elastic supports 71, four flat lower supports 72, and twelve reinforcing bodies 73. The support mechanism 7 has a structure in which three pairs of elastic supports 71, each of which is a pair of two elastic supports 71, are alternately sandwiched by lower supports 72 at side ends 71a in the width direction. It has a structure, and the total length dimension in the center axis XX direction is set to be substantially equal to the total length of the stator core of the stator 2. Similar to the conventional example, the lower portion of the elastic support 71 is formed in an inverted T-shaped surface shape having a wider width than the upper portion thereof, and the upper portion is fitted with the support mechanism mounting portion 221. It has a through hole 74. This elastic support 71
Plays a role of elastically supporting the stator 2 as in the case of the conventional example, and a main portion for elastically supporting the stator 2 is an upper portion having a short width dimension.

The elastic support 71 is fitted to the outer surface of the stator 2 by fitting the through hole 74 into the support mechanism mounting portion 221, attaching the welding seat 23 from the outside, and integrally welding. It is fixed. The elastic support 71 is fixed to a side surface of the lower support 72 by a welding method at a side end 71a of the lower portion. The lower support 72 has the surface shape shown in FIG. 3, and has a cover 6 at each of the side end portions 72a.
1 and at each of the lower ends 72b, 72b
2 and fixed by a welding method. This lower support 72
With respect to the support mechanism, it has the same role as the flat member of the stator lower frame in the case of the conventional example, and has a strength member as an integral structure with the stator lower frame 6 and three refrigerant gases. Also serves as a partition plate for evenly flowing through the cooler 8.

In this case, the reinforcing member 73 has a cross-sectional shape obtained by cutting a cylinder in half, and has a length equal to the width of the lower portion of the elastic support 71. Each reinforcing member 73 is fixed to each side surface of the lower portion of the elastic support 71 by a welding method, and its end is welded to the side surface of the lower support 72 together with the side end 71 a of the elastic support 71. It is fixed by the method. The features of the support mechanism 7 according to the present invention with respect to the conventional example are as follows. As for the elastic support 71, the center position of the through hole 74 and the center position of the side end 71 a fixed to the lower support 72. (Reinforcement 73
Length L (see FIGS. 1 and 3)
Are made longer than the conventional example, and the reinforcing member 73 is provided. This increase in the interval length L is obtained by setting the height dimension H of the stator 2 higher than the height dimension H ₆ of the upper edge of the stator lower frame 6.

Since the turbine generator 1 according to the embodiment of the present invention shown in FIGS. 1 to 3 has the above-described structure, the upper edge of the stator lower frame 6 has a dimension ΔH larger than the height H.
Only when the elastic support 71 is mounted on the outer side of the stator 2, the lower frame 6
Does not hinder the work, the work of mounting the elastic support 71 is extremely easy, the number of work steps can be reduced, and the manufacturing cost can be reduced.

Further, by setting the height H of the stator 2 higher than the height H ₆ of the upper edge portion of the lower frame 6 of the stator, as described above, the interval length L is made larger than in the conventional example. And the spring constant in the direction perpendicular to the plate surface of the elastic support can be reduced. That is, since the elastic support 71 according to the present invention can increase the damping ability with respect to the mechanical vibration as compared with the conventional example, the design and manufacture of the stator and the rotor with respect to the mechanical vibration generated by the main magnetic flux. Such conditions can be relaxed to reduce the manufacturing cost.

Further, the supporting mechanism 7 according to the present invention has a reinforcing member 73. When the side end 71a of the elastic supporting member 71 is fixed to the lower supporting member 72 by welding, the reinforcing member 73 is provided.
Are also integrally fixed to the lower support 72 by a welding method. Thus, when a torsional torque is applied to the fixed portion between the elastic support 71 and the lower support 72, the stress due to the torsional torque is reduced by the elastic support 71.
And the fixed portion at the end of the reinforcing member 73 can be shared.

In particular, since the reinforcing member 73 has a cross-sectional shape like a cylinder cut in half, and its long perimeter can be used for forming the fixing portion, the local stress value generated in the welding portion as the fixing portion can be easily reduced. it can. Therefore, even in the case of the elastic support 71 having an extended length dimension, the disposition angle of the elastic support 71 can be the same allowable deviation angle as that of the conventional example. That is, it is possible to eliminate a serious restriction condition regarding an increase in the length of the elastic support 71, and to freely use the elastic support 71 having an increased damping ability with respect to mechanical vibration.

In the above description, the turbine generator 1 has the cooler 8 disposed below the stator 2. However, the present invention is not limited to this. For example, the cooler 8 may be disposed above the stator 2 or Even if it is arranged on the stator upper frame, the center axis X-
If the height H of the X from the top surface of the base 9 can be set higher than in the conventional example, the cooler 8 may be arranged above the stator 2 or on the stator upper frame.

In the above description, the support mechanism 7 has the reinforcing member 73. However, the present invention is not limited to this. For example, in the case of a turbine generator having a relatively small force due to short-circuit torque, the supporting mechanism 7 is not necessarily reinforced. The body 73 need not be worn.

In the above description, the reinforcing member 73 of the support mechanism 7 has a sectional shape obtained by cutting a cylinder in half. However, the present invention is not limited to this. For example, the reinforcing member 73 has a sectional shape obtained by cutting a regular hexagon in half. It may be a shape or a cross-sectional shape such as an isosceles triangle (a shape obtained by cutting a regular square in half). Furthermore, in the above description, the rotating electric machine has been described as a turbine generator, but is not limited thereto, and may be, for example, any rotating electric machine.

[0026]

The rotary electric machine according to the present invention has the following effects by adopting the configuration described in the section of the means for solving the above problems.

By adopting the constitution according to the first aspect of the present invention, the operation of attaching the elastic support to the outer surface of the stator is facilitated, and the mechanical vibration is reduced. Adoption of an elastic support having a large damping capacity makes it possible to relax the conditions such as the design and manufacture of the stator and rotor against the mechanical vibration force generated by the main magnetic flux.
For these reasons, it is possible to reduce the manufacturing cost of the rotating electric machine.

By adopting the configuration according to the item (2) of the means for solving the above problems, the center axis X of the stator
Since the height dimension of -X from the upper surface of the base can be set high without creating useless space, a rotating electric machine having the above-described effects can be easily manufactured.
Furthermore, by adopting the configuration according to the third aspect of the means for solving the above problems, it becomes possible to reduce a local stress value generated at a portion where the side end of the elastic support is fixed. The degree of freedom regarding the use of an elastic support having a large damping ability with respect to mechanical vibration can be improved.

[Brief description of the drawings]

FIG. 1 shows an outline of a rotating electric machine according to an example of an embodiment of the present invention;
Half cut section view in B and CC

FIG. 2 is a sectional view taken along line AA of a main part in FIG.

FIG. 3 is a sectional view taken along line DD in FIG. 2 showing a support mechanism.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Rotary electric machine (turbine generator) 2 Stator 4 Stator frame 4a Seam 5 Stator upper frame 6 Stator lower frame 7 Support mechanism 71 Elastic support 72 Lower support 73 Reinforcement 8 Cooler 9 Foundation

Claims (3)

[Claims] 1. A stator, a rotor combined with the stator, a cooler for cooling the stator and the rotor, a stator upper frame for covering an upper portion of the stator, and a lower portion for covering a lower portion of the stator. A rotating electric machine comprising a stator frame having a stator lower frame mounted on the stator and a support mechanism for elastically supporting the stator on the stator lower frame, wherein the stator frame comprises a stator upper frame. The lower frame of the stator and the lower edge of the upper frame of the stator are combined with the upper edge of the lower frame of the stator to form an integral frame, and the support mechanism has an inverted T-shaped surface shape. A flat elastic support fixed to the side of the outer surface of the stator at the upper portion to elastically support the stator; a flat elastic support disposed at the lower side of the stator and fixed to the lower frame of the stator; A flat lower support for fixing the side of the elastic support, and a portion for fixing the elastic support to the side of the outer surface of the stator is fixed A rotating electric machine, wherein the position of the upper edge of the stator lower frame is set to be higher than the upper edge of the lower child frame. 2. The rotating electric machine according to claim 1, wherein the cooler is housed in the stator frame and is arranged below the stator. 3. The rotary electric machine according to claim 1, wherein the support mechanism has a cross-sectional shape obtained by cutting a cylindrical body in half on a side surface of the elastic support at a portion fixed to the lower support. A rotating electric machine comprising a reinforcement.