RU2545148C1 - Stationary electric induction device - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: stationary electric induction device includes magnetic conductor with multiple bars, winding around at least one of multiple bars of the magnetic conductor, lower yoke under the winding, a pair of lower clamping plates of the winding, positioned on a pair of side surface of the lower yoke, and lower connection plate connecting the pair of lower winding clamping plates. Tank features lower plate and houses the magnetic conductor of stationary electric induction device with windings. Damping element is placed at least either between lower connection plate and lower plate or between lower winding clamping plates and lower connection plate, and features a package formed by multiple hard solid elements and multiple soft viscoelastic elements laid in staple.

EFFECT: additional noise reduction.

20 cl, 21 dwg

Description

Cross reference to related application

[0001] This application is based on and claims the priority of Japanese patent application No. 2012-230501, filed October 18, 2012, the contents of which are fully incorporated into this description by reference.

Technical field

[0002] The embodiments described herein relate generally to a stationary induction electrical device.

State of the art

[0003] In recent years, the control of noise pollution has gained particular importance from the point of view of environmental protection, and it is highly desirable to realize a low noise level of a stationary induction electric device, for example a transformer.

[0004] The stationary induction electric device is configured by enclosing the main body of the stationary induction electric device having an iron core and a winding in a tank and converts voltage, etc. When the electricity is turned on, the iron core and the winding of the main body of the stationary induction electric device vibrate. The winding vibrates under the influence of electromagnetic mechanical force during the inclusion of electricity. The iron core vibrates when magnetostriction is generated due to excitation by the winding.

[0005] Vibration of the main body of the stationary induction electric device extends to the tank surrounding the main body, and the side surfaces of the tank vibrate, emitting sound to the periphery of the tank, as a result of which noise is generated from the stationary induction electric device.

[0006] In order to prevent the emission of sound from a stationary induction electric device, it is possible to provide for the conclusion of the stationary induction electric device in a soundproof structure made of steel plates, etc. However, in this method, the problem is to increase the installation area. In addition, you can consider a method of providing a soundproof panel on the periphery of the tank. However, this method requires a design in which the soundproof panel does not vibrate due to vibration of the side surfaces of the tank.

[0007] In order to implement noise reduction without adding the structure to a stationary induction electrical device, measures are also taken to reduce the vibration of the side surfaces of the tank. Mention may be made of a method in which reinforcing materials are attached to the side surfaces of the tank to provide vibration nodes on the side surfaces of the tank, a method in which the size of the plate portion is set such that the plate portion does not have a natural frequency near the main frequency component of the vibration, etc.

[0008] Next, a method for reducing vibration of the side surfaces of the tank will be described with reference to FIG. 20 and FIG. 21. As shown in these drawings, the main body 10 of the stationary induction electric device is sealed in the tank 20. A plurality of reinforcing materials 61 are attached to the side surfaces of the tank 20. The portion surrounded by the reinforcing materials 61, the upper end and the lower end of the side surface of the tank 20 is a portion 62 plates. In particular, the plate portion 62 indicates a portion formed only from the plate material from which the tank 20 itself is made.

[0009] As described above, traditionally a plurality of pieces of reinforcing materials 61 are attached to the side surfaces of the tank 20 to provide vibration nodes on the side surfaces of the tank 20 and thereby reduce the vibration amplitude of the side surfaces of the tank 20. In addition, adjusting the attachment positions of the reinforcing materials 61 to set the size of the plate portion 62 so that the plate portion 62 does not have an eigenfrequency near the main frequency component of the vibration, vibration amplification due to resonance can be avoided.

[0010] However, in a conventional stationary induction electric device, noise reduction is not always implemented sufficiently, as described below. In particular, a plurality of pieces of reinforcing materials 61 are attached to the side surfaces of the tank 20, and the positions of the reinforcing materials 61 are defined as vibration units. However, the side surfaces of the tank 20 themselves are continuously formed, and vibration is inevitably generated on all side surfaces of the tank 20. The noise volume depends on the area of the vibration, so if vibration is generated on all side surfaces of the tank 20, the noise reduction is insufficient.

[0011] Furthermore, the size of the plate portion 62 is determined by adjusting the positions of the reinforcing materials 61 so that the plate portion 62 does not have a natural frequency near the main frequency component of the vibration. However, the plate portion 62, as described above, has a shape in which it is easy for it to have a natural frequency, and the natural frequency of all the plate sections 62 is difficult to deviate from a frequency close to the main vibration frequency.

[0012] An object of the present invention is to provide a stationary induction electric device that realizes further noise reduction by suppressing vibration propagation from the main body of the stationary induction electric device to the tank.

[0013] A stationary induction electric device of an embodiment includes: a main body of a stationary induction electric device, having: a plurality of arms of a magnetic circuit; a winding wound around at least one of the plurality of arms of the magnetic circuit; upper yoke located above the winding; lower yoke located under the winding; a pair of upper winding pressure plates located on a pair of side surfaces of the upper yoke; a pair of lower winding pressure plates located on a pair of side surfaces of the lower yoke; an upper connecting plate connecting a pair of upper winding pressure plates; and a lower connecting plate connecting a pair of lower winding pressure plates; a tank having a lower plate and comprising the main body of a stationary induction electrical device; insulating oil poured into the tank; and a damping element located at least either between the lower connecting plate and the lower plate, or between the lower pressure plates of the winding and the lower connecting plate, and having a stack formed of a plurality of solid elements having rigidity and many soft elements having the property viscoelasticity, which are stacked for placement.

Brief Description of the Drawings

[0014] FIG. 1 is a transparent front view of a stationary induction electric device according to the first embodiment.

[0015] FIG. 2 is a transparent side view of a stationary induction electric device according to the first embodiment.

[0016] FIG. 3 is a cross-sectional view of a damping element of a stationary induction electric device according to the first embodiment.

[0017] FIG. 4 is a perspective view of a damping element of a stationary induction electric device according to a first embodiment.

[0018] FIG. 5 is a transparent front view of a stationary induction electric device according to modified Example 1.

[0019] FIG. 6 is a transparent side view of a stationary induction electric device according to modified example 1.

[0020] FIG. 7 is a perspective view showing a damping element of a stationary induction electrical device according to modified Example 2.

[0021] FIG. 8 is a perspective view showing a stack of a stationary induction electric device according to modified Example 3.

[0022] FIG. 9 is a perspective view showing a stack of a stationary induction electric device according to modified Example 4.

[0023] FIG. 10 is a perspective view showing a damping element of a stationary induction electric device according to modified Example 5.

[0024] FIG. 11 is a perspective view showing part of a stationary induction electric device according to modified Example 6.

[0025] FIG. 12 is a perspective view showing part of a stationary induction electric device according to modified Example 7.

[0026] FIG. 13 is a perspective view showing part of a stationary induction electric device according to modified Example 8.

[0027] FIG. 14 is a perspective view showing part of a stationary induction electric device according to modified Example 9.

[0028] FIG. 15 is a transparent front view of a stationary induction electric device according to a second embodiment.

[0029] FIG. 16 is a transparent side view of a stationary induction electric device according to a second embodiment.

[0030] FIG. 17 is a transparent front view of a stationary induction electric device according to a third embodiment.

[0031] FIG. 18 is a transparent side view of a stationary induction electric device according to a third embodiment.

[0032] FIG. 19 is a transparent side view of a stationary induction electric device according to a fourth embodiment.

[0033] FIG. 20 is a transparent side view of a stationary induction electric device according to a traditional example.

[0034] FIG. 21 is a front view of a stationary induction electric device according to a traditional example.

Detailed description

[0035] Next, with reference to the drawings, embodiments of a stationary induction electric device in which measures are taken to provide vibration isolation will be described in detail.

First Embodiment

[0036] A first embodiment will be described with reference to FIG. 1-4. Note that FIG. 1 is a transparent front view of a stationary induction electric device according to the present embodiment. FIG. 2 is a transparent side view of a stationary induction electric device. FIG. 3 and FIG. 4 are a sectional view and a general view, respectively, of a damping element 30.

[0037] As shown in FIG. 1 and FIG. 2, a stationary induction electric device has a main body 10 of a stationary induction electric device, a tank 20, and damping elements 30.

[0038] The main body 10 of the stationary induction electric device has a plurality of arms 11 of the magnetic core, winding 12, upper yoke 13a, lower yoke 13b, a pair of upper winding pressure plates 14a, a pair of lower winding pressure plates 14b, a pair of upper gaskets 15a, a pair of lower gaskets 15b , upper connection plates 16a and lower connection plates 16b.

[0039] Each of the arms 11 of the magnetic circuit is made in the form of a lined iron core formed by layering a plurality of electromagnetic steel plates. A plurality of arms 11 of the magnetic circuit are connected to each other by an upper yoke 13a and a lower yoke 13b. A winding 12 is wound around any of the plurality of arms 11 of the magnetic circuit. In this case, the three arms 11 of the magnetic circuit are adjacent. A pair of shoulders 11 of the magnetic circuit, located on both sides, are located on the right and left, while the winding 12 is located in a central position. In addition, the central arm 11 of the magnetic circuit is inserted in the center of the winding 12 (the coil 12 is wound around the arm 11 of the magnetic circuit).

[0040] On both side surfaces of the upper yoke 13a is a pair of upper winding pressure plates 14a. On both side surfaces of the lower yoke 13b is a pair of lower winding pressure plates 14b. A pair of upper gaskets 15a is located between the winding 12 and the upper pressure plates 14a of the winding. A pair of lower gaskets 15b is located between the winding 12 and the lower pressure plates 14b of the winding. A pair of upper winding pressure plates 14a are connected by upper connection plates 16a. A pair of lower winding pressure plates 14b are connected by lower connection plates 16b.

[0041] The tank 20 has an upper plate 21 (tank cap), a lower plate 22 and a plurality of side plates 23, and includes a main body 10 of a stationary induction electric device together with an insulating oil (insulating medium) 27.

[0042] Damping elements 30 are sandwiched between the lower connecting plates 16b and the lower plate 22 (the main body 10 of the stationary induction electric device is enclosed in the tank 20 through the damping elements 30).

[0043] Note that in the present embodiment, three damping elements 30 are provided, but the number of elements can be appropriately changed.

[0044] The damping element 30 has a stack of 31 (hard elements 32 and soft elements 33) and a box-shaped element 34. The stack 31 is formed by stacking hard elements 32 (e.g., metal plates) and soft elements 33 (e.g., soft plates) and is enclosed in a box-shaped element 34.

[0045] FIG. 3 and FIG. 4, each of the solid elements 32 and each of the soft elements 33 are stacked in alternating order. However, the amount of each of the solid elements 32 and the soft elements 33, which are stacked in alternating order, is not always equal to one. For example, you can also stack in alternating order one (or several) solid (s) element (s) 32 and several soft elements 33.

[0046] The solid member 32 is thin and stiff. The solid member 32 may be formed of a metal plate, which is, for example, an electromagnetic steel plate, a stainless steel plate, or a copper plate having a thickness of not less than 0.1 mm and not more than 3 mm. If the thickness is 0.1 mm or less, there is the possibility of deformation due to the inability to provide the rigidity necessary for damping. If you set the thickness to 3 mm or more, damping, in contrast, is reduced due to excessive stiffness.

[0047] Friction occurs on each of the solid elements 32, which helps to suppress vibration, therefore, the number of solid elements 32 forming the stack 31 is preferably large. The number of solid elements 32 can be set equal, for example, from 10 to 100.

[0048] The soft member 33 is thin and has a material damping characteristic. The soft member 33 may be formed of a fibrous element made in the form of a plate and having a thickness of not less than 1 mm and not more than 8 mm. As the fiber element, mention may be made of cotton, pulp, stainless steel yarn, fiberglass, carbon fiber or a whisker of potassium titanate. If the thickness is 1 mm or less, damping and durability are low. Even if the thickness is set to 8 mm or more, one does not have to expect an increase in damping, and when stacking soft elements 33 and solid elements 32, the thickness of stack 31 is excessively increased.

[0049] Friction occurs on each of the soft elements 33, which helps to suppress vibration, therefore, the number of soft elements 33 forming the stack 31 is preferably large. The number of soft elements 33 can be set equal, for example, from 10 to 100.

[0050] As an example of a “fibrous element formed in the form of a plate”, press punches can be mentioned. A press press is a product obtained by forming layers of cotton or pulp and squeezing and drying the layers, and it has mechanical strength, flexibility and electrical insulation properties. The press-absorber absorbs the insulating oil 27 to increase the vibration damping characteristics, therefore, it is suitable for use in a tank 20 filled with insulating oil 27.

[0051] As an example, stack 31 can be formed by alternately stacking 25 pieces of pressboard, each of which has a thickness of 1 mm, and 25 metal plates, each of which has a thickness of 0.5 mm.

[0052] As an example of a “fiber element formed in the form of a plate”, molded stainless steel yarn can be mentioned. Molded stainless steel yarn is made by weaving one stainless steel yarn, and, for example, compressing and molding the resulting material. Molded stainless steel yarn is formed by weaving a fiber element (in this case, stainless steel yarn), due to which it has a relatively large internal friction, and a good vibration absorption characteristic.

[0053] The soft member 33 may also have, in addition to the “fibrous member formed in the form of a plate”, a base material filled with the fibrous member. As the main material, mention may be made of plastic, for example polytetrafluoroethylene (PTFE), epoxy resin, polyester resin and the like.

[0054] The soft member 33 can be formed by incorporating fiberglass, carbon fiber, a potassium titanate whisker, and the like. in the main material. For example, FRP (fiber) formed by incorporating fiberglass or carbon fiber into plastic can be used as soft member 33.

[0055] Furthermore, the soft member 33 can also have many types of fibrous elements. For example, you can use a mixed filling material formed from carbon fiber and a whisker of potassium titanate. By introducing the mixed filling material into PTFE, it is possible to provide fatigue shear strength of 106 cycles or more in the temperature range from room temperature to 333 K, contact pressure strength of 10 MPa and stress under load of 2 MPa.

[0056] The box-shaped member 34 is formed of an insulating material and encloses a stack 31. By positioning the stack 31 in the box-shaped member 34, positional displacement of the solid members 32 and soft members 33 can be prevented during transportation or assembly of the damping member 30, thereby increasing working capacity. In addition, using the insulating material as the material of the box-shaped element 34, it is possible to provide electrical insulation of the solid elements 32 (for example, metal plates).

[0057] In the present embodiment, the main body 10 of the stationary induction electric device is enclosed in the tank 20 through the damping elements 30 located between the lower connecting plates 16b and the lower plate 22. The vibration is propagated from the main body 10 of the stationary induction electric device to the lower plate 22 only through the damping elements 30. Thanks to the above construction, the propagation of vibration from the main body 10 of the stationary induction electrically of the device to the bottom plate 22 is suppressed by the two operations described below provided by the damping elements 30.

[0058] The first operation is to reduce vibration realized by vibration isolation. Vibration reduction can be modeled by a spring, load, and shock absorber system, which is a system with one degree of freedom. Due to the electromagnetic mechanical force generated in the winding 12 and the magnetostriction generated in the arms 11 of the magnetic circuit, the upper yoke 13a and the lower yoke 13b, a driving force F _{o is} generated in the main body 10 of the stationary induction electric device. In the driving force F _o , the force transmitted to the lower plate 22 through the damping element 30 is set as the force F. Moreover, the force transfer coefficient γ from the main body 10 of the stationary induction electric device to the lower plate 22 can be represented according to the following equation.

[0059]

[0060] In this case, ζ (= (c / 2) ∙ (mk) ^1/2 ) is the damping coefficient, m is the mass of the main body 10 of the stationary induction electric device, k is the stiffness coefficient of the damping element 30, c is the damping constant the damping element 30, ν (= f / fn) denotes the frequency ratio, fn (= (1 / (2π)) · (k / m) ^1/2 ) denotes the natural frequency, and f denotes the frequency of the exciting force F _o .

[0061] If the force transfer coefficient γ is less than or equal to 1, the force transmitted from the main body 10 of the stationary induction electric device to the lower plate 22 is reduced. For this reason, the transmission coefficient γ becomes 1 or less in the range where the frequency ratio is greater than or equal to √2, as a result of which the vibration decreases. The frequency f of the exciting force F _o is the main vibration frequency under the influence of electromagnetic mechanical force and magnetostrictive force in the main body 10 of a stationary induction electric device. To reduce vibration, the condition “natural frequency fn≤f / √2” must be fulfilled (more preferably, “natural frequency fn≤f / 2”). It is necessary to determine the material, thickness and number of hard elements 32 and soft elements 33 that satisfy the above ratio.

[0062] Note that the stiffness coefficient k varies depending on the pressure applied to the damping element 30 (mass of the main body 10 of the stationary induction electrical device). In particular, it is preferable that the pressure be sufficiently large, since the stiffness coefficient k (damping coefficient ζ) takes the appropriate value.

[0063] By using a damping element 30 that satisfies the condition, vibration propagation from the main body 10 of the stationary induction electric device to the bottom plate 22 is suppressed, which makes it possible to reduce the vibration of the tank 20, namely, noise reduction.

[0064] The second operation is to reduce vibration due to energy dissipation in the damping element 30. Due to frictional forces generated between the solid elements 32 and the soft elements 33, and energy dissipation due to material damping in the soft elements 33, the propagation of vibration from the stationary main body 10 is suppressed. an induction electrical device to the bottom plate 22. As a result, the vibration of the tank 20 is reduced, and noise reduction can be realized.

[0065] As described above, according to the present embodiment, due to the interlaying of the damping elements 30 between the main body 10 of the stationary induction electric device and the lower plate 22, the vibration of the tank 20 is reduced, and a noise reducing effect can be achieved.

[0066] In the present embodiment, it is not necessary to provide a new design for reducing noise on the outside or periphery of the tank 20, which also leads to a reduction in cost. In particular, noise reduction can be achieved by positioning the damping elements 30 between the lower connecting plates 16b and the lower plate 22 inside the tank 20.

[0067] Furthermore, in the present embodiment, since the damping elements 30 are sandwiched between the main body 10 of the stationary induction electric device and the bottom plate 22, the pressure applied to each of the damping elements 30 increases, resulting in a stiffness coefficient k (damping coefficient ζ) of each of the damping elements 30 takes on an appropriate value, which is favorable.

Modified Example 1

[0068] FIG. 5 and FIG. 6 are a transparent front view and a transparent side view, respectively, of a stationary induction electrical device according to modified Example 1.

[0069] In a modified example 1, damping elements 30 are sandwiched between the lower connecting plates 16b and the lower plate 22 (the main body 10 of the stationary induction electric device is enclosed in the tank 20 through the damping elements 30). In this regard, modified example 1 is identical to the first embodiment. The present modified example 1 differs from the first embodiment in that reinforcing elements 50 of the bottom plate are provided. Each of the reinforcing elements 50 of the lower plate is located at the position of the outer side of the lower plate 22 at the position where the damping element 30 is located, namely, at the position facing the damping element 30 through the lower plate 22.

[0070] By placing each of the damping elements 30 and each of the reinforcing elements 50 of the bottom plate in a position where they are facing each other (at approximately the same position) through the bottom plate 22, the stiffness of the bottom surface of the damping element 30 increases. Accordingly, this prevents the damping element 30 from vibrating together with the lower plate 22. In addition, since the lower plate 22 receives the vibration of the damping element 30 and returns the vibration to the damping element 30, the energy dissipation effect provided by the damping element 30 is further enhanced.

[0071] As described above, in the present modified example, by providing reinforcing elements 50 of the bottom plate at positions facing the damping elements 30 through the bottom plate 22, a stationary induction electric device capable of further reducing noise can be provided.

[0072] Note that although three damping elements 30 and three reinforcing elements 50 of the lower plate are provided in the present modified example, the number of these elements can be appropriately varied.

Modified Example 2

[0073] FIG. 7 is a perspective view showing the damping element 30 of the stationary induction electric device according to modified Example 2. The damping element 30 has an upper plate 35a and a lower plate 35b located above and below the stack 31. Note that, although the box-shaped element 34 is not shown, it is not shown there will be problems if the item is provided.

[0074] As the upper plate 35a, an electromagnetic steel plate, a stainless steel plate, or a copper plate can be used. The thickness d3a of the upper plate 35a is about 10% (for example, 10% ± 5%) of the thickness Dt of the damping element 30. If the thickness d3a is significantly more than 10% of the thickness Dt, it is not possible to obtain the thickness necessary to provide the damping effect of the stack 31. On the other on the other hand, if the thickness d3a is significantly less than 10% of the thickness Dt, when the thickness Dt of the damping element 30 is small, the upper plate 35a may be deformed.

[0075] As the bottom plate 35b, an electromagnetic steel plate, a stainless steel plate, or a copper plate can be used. The thickness d3b of the bottom plate 35b is about 10% (for example, 10% ± 5%) of the thickness Dt of the damping element 30. If the thickness d3b is much more than 10% of the thickness Dt, it is not possible to obtain the thickness necessary to ensure the damping effect of the stack 31. On the other on the other hand, if the thickness d3b is significantly less than 10% of the thickness Dt, when the thickness Dt of the damping element 30 is small, the lower plate 35b may be deformed.

[0076] Each of the total thickness d1t (= d11 + d12 + ··· + d1m) of the solid elements 32 and the total thickness d2t (= d21 + d22 + ··· + d2n) of the soft elements 33 is approximately 40% (eg, 40% ± 5%) of the thickness Dt of the damping element 30. The total number of hard elements 32 and soft elements 33 (m + n) can be set equal, for example, from 4 to 20. The total thicknesses d1t and d2t of the corresponding solid elements 32 and soft elements 33 are set equal approximately the same thickness. If the thickness d2t is significantly greater than 40% of the thickness Dt, it is not possible to obtain the thickness of the upper plate 35a and the lower plate 35b, which allows for strength. On the other hand, if the thickness d2t is significantly less than 40% of the thickness Dt, vibration damping is reduced.

[0077] In this case, the ratio of the width (transverse dimension, length in the short side direction of the lower connecting plate 16b) Lb to the thickness (height) Dt of the damping element 30 (= Lb / Dt) is preferably approximately 1.0 (for example, 1 , 0 ± 0.1) or more. This ensures stability during earthquakes and transportation.

Modified Example 3

[0078] FIG. 8 is a perspective view showing a stack 31 of a stationary induction electric device according to a modified example 3. The solid member 32 of stack 31 has a “pair of solid plates 321 arranged side by side in the longitudinal direction of the lower connection plate 16b”. This makes it possible to facilitate the deformation of the stack 31 corresponding to the bending vibration in the longitudinal direction of the lower connecting plate 16b, which facilitates the suppression of the bending vibration in the longitudinal direction.

[0079] In this case, it is possible to provide such a design in which a pair of solid plates 321 are in a connected state. For example, a cut may be made in one solid element 32 to create a solid element 32 according to modified Example 3.

[0080] In this case, the position of the boundary of the pair of hard plates 321 is set differently for each of several instances (from 1 to 10 copies) of the solid elements 32. Due to the above construction, the boundary (for example, the connection portion) of the pair of solid plates 321 is easily bent, which allows significant suppression of vibration.

Modified Example 4

[0081] FIG. 9 is a perspective view showing the stack 31 of a stationary induction electric device according to modified Example 4. The soft member 33 of stack 31 has a plurality of soft plates 331 spaced at intervals to form a slit (oil groove) 36 through which the insulating oil 27 flows. Creating a slit ( oil groove) 36 as the channel of the insulating oil 27, vibration damping with the insulating oil 27 can be realized. Note that the width of the slit 36 can be set equal, for example, from 3 mm to 20 mm.

Modified Example 5

[0082] FIG. 10 is a perspective view illustrating a damping element 30 of a stationary induction electric device according to a modified example 5. The damping element 30 has a plurality of stacks 311 arranged side by side in the longitudinal direction of the lower connection plate 16b. In particular, a plurality of stacks 311 (divided stack 31) are sandwiched between the lower connecting plate 16b and the lower plate 22. Thus, the phase difference of the vibration received by the damping element 30 is reduced in the same plane, and the vibration reduction rate of the damping element 30 is increased. As a result of this, the vibration transmitted from the lower connecting plate 16b to the lower plate 22 is further reduced, and the vibration of the tank 20 is also reduced, as a result of which the noise is further reduced.

Modified Example 6

[0083] FIG. 11 is a perspective view showing part of a stationary induction electric device according to modified Example 6. A cover 40 (guide) corresponding to at least a portion of the outer periphery of the damping element 30 is located on the lower plate 22.

[0084] The cover 40 has a lower plate 41 and holding elements 42. The lower plate 41 holds the damping element 30. The holding elements 42 are corner elements holding the four corners of the damping element 30 and preventing the damping element 30 from moving on the lower plate 41. The height H1 of the holding plate element 42 above the upper surface of the bottom plate 41 is approximately 90% (eg, 90% ± 5%) of the height H0 of the damping element 30. If the height H1 is significantly greater than 90% of the height H0 when the damping element ment 30 is deformed due to the mass of the stationary induction electric device, the element can come into contact with the holding element 42. On the other hand, if the height H1 is significantly less than 90% of the height H0, the area of the part of the damping element 30 protruding from the holding element 42 increases, which adversely.

Modified Example 7

[0085] FIG. 12 is a perspective view showing part of a stationary induction electric device according to modified Example 7. A guide 43 corresponding to at least a portion of the outer periphery of the damping element 30 is located on the lower plate 22. A guide 43 is attached to the periphery of the damping element 30 on the lower plate 22.

[0086] As a result, the positional displacement of the damping element 30 due to shock during transportation, earthquake, and the like is suppressed, and the inclination of the main body 10 of the stationary induction electric device due to the positional displacement of the damping element 30 is prevented. In addition, the entry of the damping element 30 in contact with another part.

Modified Example 8

[0087] FIG. 13 is a perspective view showing part of a stationary induction electric device according to modified Example 8. As shown in the present drawing, the stationary induction electric device has sleeves 44 connecting the damping element 30 and the lower connection plate 16b. As a sleeve 44, for example, a glass clamp (a tape formed by incorporating fiberglass into plastic) can be used.

[0088] By bonding the lower connecting plate 16b and the damping element 30 using the sleeves 44, the positional displacement of the damping element 30 due to shock during transport, earthquake, and the like is suppressed, and the inclination of the main body 10 of the stationary induction electric device due to the positional displacement of the damping element 30. In addition, it is possible to prevent the damping element 30 from coming into contact with another part.

[0089] Furthermore, during the assembly of the main body 10 of the stationary induction electric device, the lower connecting plate 16b and the damping element 30 are pulled together by the sleeves 44, and the assembly can remain in this state (the main body is dried and placed in the tank 20), thereby increasing working capacity.

Modified Example 9

[0090] FIG. 14 is a perspective view showing part of a stationary induction electric device according to modified example 9. As shown in the present drawing, the lower connecting plate 16b of the stationary induction electric device has a groove 161. A groove 161 is provided on the surface of the lower connecting plate 16b that faces the lower plate 22 The damping element 30 is located between the lower connecting plate 16b and the lower plate 22 and is inserted into the groove 161.

[0091] Since the damping element 30 is inserted into the groove 161 provided on the lower connecting plate 16b, the height of the main body 10 and the tank 20 of the stationary induction electric device can be reduced. As a result of this, it becomes easier to implement a design satisfying the transportation limit, and the amount of steel and insulating medium used in the product can be reduced.

[0092] As a result, the positional displacement of the damping element 30 due to shock during transportation, earthquake, and the like is suppressed, and the inclination of the main body 10 of the stationary induction electric device due to the positional displacement of the damping element 30 is prevented. In addition, the entry of the damping element element 30 in contact with another part.

Second Embodiment

[0093] A second embodiment will be described with reference to FIG. 15 and FIG. 16. Note that FIG. 15 is a transparent front view of a stationary induction electric device of the present embodiment. FIG. 16 is a transparent side view of a stationary induction electrical device.

[0094] As shown in FIG. 15 and FIG. 16, damping elements 30 are sandwiched between the lower pressure plates of the winding 14b and the lower connection plates 16b. The damping element 30 has a stack of 31 (hard elements 32 and soft elements 33) and a box-shaped element 34.

[0095] In the present embodiment, damping elements 30 are sandwiched between the lower wrap clamping plates 14b and the lower connecting plates 16b. As a result of this, vibration propagation from the lower pressure plates 14b of the winding to the lower connection plates 16b is effected through the damping elements 30.

[0096] Due to the above construction, due to vibration reduction by vibration isolation of the damping elements 30, frictional forces generated between the solid elements 32 and the soft elements 33, and energy dissipation due to losses in the material of the soft elements 33, vibration propagation from the lower pressure plates 14b of the winding is suppressed lower connection plates 16b. Since the vibration of the lower connection plates 16b is reduced, vibration propagation from the main body 10 of the stationary induction electric device to the lower plate 22 is suppressed, as a result of which the vibration of the tank 20 is reduced, and noise reduction can be realized.

[0097] In addition, it is not necessary to provide a new design for reducing noise on the outside of the tank 20 or the periphery of the tank 20. In particular, noise reduction can be realized by interlaying the damping elements 30 between the lower pressure plates of the winding 14b and the lower connection plates 16b, which also leads to lower costs.

[0098] In addition, in the present embodiment, since the damping elements 30 are sandwiched between the lower winding pressure plates 14b and the lower connection plates 16b, the pressure applied to each of the damping elements 30 increases, resulting in a stiffness coefficient k (damping coefficient ζ ) of each of the damping elements 30 assumes an appropriate value, which is favorable.

Third Embodiment

[0099] A third embodiment will be described with reference to FIG. 17 and FIG. 18. Note that FIG. 17 is a transparent front view of a stationary induction electric device of the present embodiment, and FIG. 18 is a transparent side view of a stationary induction electric device.

[0100] As shown in FIG. 17 and FIG. 18, damping elements 30 are sandwiched between the winding 12 and the upper winding pressure plates 14a and between the winding 12 and the lower winding pressure plates 14b. In particular, the damping elements 30 are instead of the upper gaskets 15a and the lower gaskets 15b. The damping element 30 has a stack of 31 (hard elements 32 and soft elements 33) and a box-shaped element 34. The main body 10 of the stationary induction electric device is enclosed in the tank 20 in a state in which the lower connection plates 16b come into contact with the lower plate 22.

[0101] In the present embodiment, damping elements 30 are sandwiched between the winding 12 and the upper winding pressure plates 14a and between the winding 12 and the lower winding pressure plates 14b. As a result of this, vibration propagation from the winding 12 to the upper pressure plates of the winding 14a and to the lower pressure plates of the winding 14b is effected through the damping elements 30.

[0102] Due to the above construction, due to vibration reduction by vibration isolation of the damping elements 30, friction forces generated between the solid elements 32 and the soft elements 33, and energy dissipation due to losses in the material of the soft elements 33, the vibration propagates from the winding 12 to the upper pressure plates 14a windings and to the lower pressure plates 14b of the winding is suppressed. In addition, since the vibration to the upper winding pressure plates 14a and to the lower winding pressure plates 14b is reduced, vibration propagation from the main body 10 of the stationary induction electric device to the lower plate 22 is suppressed, thereby reducing the vibration of the tank 20, and noise reduction can be realized.

[0103] In addition, there is no need to provide a new design for reducing noise on the outside of the tank 20 or the periphery of the tank 20. In particular, noise reduction can be realized by interlaying the damping elements 30 between the winding 12 and the upper pressure plates 14a of the winding and between the winding 12 and lower pressure plates 14b of the winding, which also leads to lower costs.

Fourth Embodiment

[0104] A fourth embodiment will be described with reference to FIG. 19. Note that FIG. 19 is a transparent side view of a stationary induction electric device of the present embodiment.

[0105] In the present embodiment, damping elements 30 are sandwiched between the upper yoke 13a and the upper connecting plate 16a, between the upper yoke 13a and the upper winding pressure plates 14a, between the lower yoke 13b and the lower connecting plate 16b, and between the lower yoke 13b and the lower pressing winding plates 14b. As a result of this, the propagation of vibration from the upper yoke 13a to the upper connecting plate 16a and to the upper winding pressure plates 14a, and the vibration propagation from the lower yoke 13b to the lower connecting plate 16b and to the lower winding pressing plates 14b, is effected through the damping elements 30.

[0106] Due to the above construction, due to vibration reduction by vibration isolation of the damping elements 30, the friction forces generated between the solid elements 32 and the soft elements 33, and energy dissipation due to losses in the material of the soft elements 33, vibration propagation from the shoulders 11 of the magnetic circuit and the upper the yoke 13a to the upper connecting plate 16a and the upper clamping plates 14a of the winding, and the propagation of vibration from the shoulders 11 of the magnetic circuit and the lower yoke 13b to the lower connecting plate 16b and lower rizhimnym plates 14b winding. In addition, since the vibration in the upper connecting plate 16a and the upper winding pressure plates 14a and the vibration in the lower connecting plate 16b and the lower winding pressure plates 14b are reduced, vibration propagation from the main body 10 of the stationary induction electric device to the lower plate 22 is suppressed, resulting which decreases the vibration of the tank 20. Accordingly, noise is reduced.

[0107] In addition, there is no need to provide a new design for reducing noise on the outside of the tank 20 or the periphery of the tank 20. In particular, a noise reduction effect can be achieved by interlaying the damping elements 30 between the upper yoke 13a and the upper connecting plate 16a, between the upper yoke 13a and the upper winding pressure plates 14a, between the lower yoke 13b and the lower connecting plate 16b, and between the lower yoke 13b and the lower winding pressure plates 14b inside the tank 20, which also reduces cost.

Other options for implementation

[0108] In the first to fourth embodiments, the damping element 30 is located at the position described in the following paragraphs (1) to (4), respectively,

(1) between the lower connecting plate 16b and the lower plate 22,

(2) between the lower pressure plates of the winding 14b and the lower connection plate 16b,

(3) between the winding 12 and the upper pressure plates 14a of the winding, and between the winding 12 and the lower pressure plates 14b of the winding, and

(4) between the upper yoke 13a and the upper connecting plate 16a, between the upper yoke 13a and the upper winding pressing plates 14a, between the lower yoke 13b and the lower connecting connecting plate 16b, and between the lower yoke 13b and the lower winding pressing plates 14b.

[0109] In this case, it is possible to properly combine part or all of the above options (1) to (4). For example, by combining (1) and (2), damping elements 30 (1) can also be positioned between the lower connection plate 16b and the lower plate 22, and also (2) between the lower winding pressure plates 14b and the lower connection plate 16b.

[0110] Furthermore, the stationary induction electric device of each of the above embodiments includes one winding 12 in one tank 20. In contrast, the stationary induction electric device may also include multiple windings located in one tank.

[0111] Although certain embodiments have been described, these embodiments are presented by way of example only and are not intended to limit the scope of the invention. In fact, embodiments of the invention described herein may be implemented in various other forms; in addition, various exemptions, replacements, and changes may be made regarding the form of the embodiments described herein without departing from the scope of the invention. The following claims and their equivalents are intended to cover such forms or modifications that meet the scope and spirit of the invention.

Claims (20)

1. Stationary induction electrical device containing
the main body of a stationary induction electrical device having
many shoulders of the magnetic circuit,
a winding wound around at least one of the plurality of arms of the magnetic circuit,
top yoke located above the winding
lower yoke located under the winding
a pair of upper winding pressure plates located on a pair of side surfaces of the upper yoke,
a pair of lower pressure plates of the winding located on a pair of side surfaces of the lower yoke,
an upper connecting plate connecting a pair of upper winding pressure plates, and
a lower connecting plate connecting a pair of lower winding pressure plates,
a tank having a lower plate and comprising the main body of a stationary induction electrical device,
insulating oil poured into the tank, and
a damping element located at least either between the lower connecting plate and the lower plate, or between the lower pressure plates of the winding and the lower connecting plate, and having a stack formed of many solid elements having rigidity and many soft elements having the property of viscoelasticity that are stacked for placement. 2. Stationary induction electrical device according to claim 1,
in which each of the many soft elements has a fibrous element formed in the form of a plate. 3. Stationary induction electrical device according to claim 2,
in which the fibrous element is at least any of cotton, pulp, stainless steel yarn, carbon fiber or a potassium titanate whisker. 4. Stationary induction electrical device according to claim 2,
in which each of the many soft elements has a base material filled with a fibrous element. 5. Stationary induction electrical device according to claim 1,
in which each of the many solid elements is a metal plate. 6. Stationary induction electrical device according to claim 5,
wherein each of the plurality of solid elements is an electromagnetic steel plate, a stainless steel plate, or a copper plate having a thickness of 3 mm or less. 7. Stationary induction electrical device according to claim 1,
in which the damping element has
a top plate formed of electromagnetic steel, stainless steel or copper and having a thickness of about 10%;
many solid elements having a total thickness of approximately 40%,
many soft elements having a total thickness of approximately 40%, and
a lower plate formed of electromagnetic steel, stainless steel or copper and having a thickness of about 10%. 8. The stationary induction electrical device according to claim 1,
wherein each of the plurality of soft elements has a plurality of soft plates spaced at intervals to form a gap through which the insulating oil flows. 9. Stationary induction electrical device according to claim 1,
wherein each of the plurality of solid elements has a pair of solid plates located adjacent in a longitudinal direction of the lower connection plate. 10. Stationary induction electrical device according to p. 9,
in which the position of the boundary of the pair of solid plates differs for each of from 1 to 10 instances of solid elements. 11. Stationary induction electrical device according to claim 1,
wherein the damping element has a plurality of stacks arranged side by side in the longitudinal direction of the lower connection plate. 12. Stationary induction electrical device according to claim 1,
in which the damping element further has a box-shaped insulating element that encloses a stack. 13. A stationary induction electrical device according to claim 1, further comprising
tape for attaching the damping element to the lower connecting plate. 14. Stationary induction electrical device according to claim 1,
in which the lower connecting plate has a groove in which the damping element is located. 15. Stationary induction electrical device according to claim 1,
in which the lower plate has a guide corresponding to at least part of the outer periphery of the damping element. 16. Stationary induction electrical device according to p. 15,
in which the height of the guide is approximately 90% or less than the height of the damping element. 17. A stationary induction electrical device according to claim 1, further comprising
a second damping element located between the lower pressure plates of the winding and the lower connection plate. 18. A stationary induction electrical device according to claim 1, further comprising
a plurality of third damping elements located between the winding and the pair of upper winding pressure plates and between the winding and the pair of lower winding pressure plates. 19. A stationary induction electrical device according to claim 1, further comprising
a plurality of fourth damping elements located between the upper yoke and the pair of upper winding pressure plates, between the upper yoke and the upper connecting plate, between the lower yoke and the pair of lower winding pressure plates and between the lower yoke and lower connecting plate. 20. The stationary induction electrical device according to claim 1, further comprising
reinforcing material located at the position of the outer surface of the bottom plate, where it faces the damping element through the bottom plate.

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