JP3578508B2 - Stationary induction electrical equipment - Google Patents

Description

[0001]
[Industrial applications]
The present invention relates to a stationary induction electric device such as a transformer and a reactor.
[0002]
[Prior art]
As shown in FIGS. 6 and 7, this type of conventional stationary induction electric device includes an iron core 4 including a plurality of legs 1 and a lower yoke 2 and an upper yoke 3 connecting the legs 1 to each other. A lower core fastener 5 for tightening the lower yoke 2, an upper core fastener 6 for tightening the upper yoke 3, a coil 7 attached to the leg 1 of the iron core 4, and a coil provided integrally with the lower core fastener 5. A stationary device comprising: a lower coil fastening device 8 that supports the lower portion 7 from the lower side; and an upper coil fastening device 9 that is provided integrally with the upper core fastening device 6 and tightens the coil 7 with the lower coil fastening device 8. The induction electric device main body 10 is mounted on a bottom wall of a case (not shown), and the inside of the case is filled with insulating oil.
[0003]
The lower iron core fastener 5 is formed by tightening a pair of lower iron core fasteners 11 made of C-shaped grooved steel arranged on both sides of the lower yoke 2 and narrowing the gap between the lower iron core fasteners 11. The lower yoke 2 includes a yoke fastening bolt 12 and a yoke fastening nut 13. In this case, the upper flange of the lower iron core fastener 11 made of channel steel is used as the coil lower fastener 8.
[0004]
The upper core fastener 6 is formed by tightening a pair of upper core fasteners 14 made of a C-shaped grooved steel disposed on both sides of the upper yoke 3 and narrowing a gap between the upper core fasteners 14. It comprises a yoke tightening bolt 15 for tightening the upper yoke 3 and a yoke tightening nut 16. In this case, the lower flange of the upper core clamp 14 made of a channel steel is used as the coil upper clamp 9.
[0005]
A coil holding insulator 17 is provided between the lower part of the coil 7 and the lower coil fastener 8 to allow oil to flow therethrough, and allows the oil to flow between the upper part of the coil 7 and the upper coil fastener 9. The coil 7 is tightened from above and below by a coil tightening bolt 19 and a coil tightening nut 20 for tightening between the coil lower tightening tool 8 and the coil upper tightening tool 9 with an allowable coil holding insulator 18 interposed. .
[0006]
[Problems to be solved by the invention]
However, in such a conventional stationary induction electric device, since the lower coil fastening tool 8 and the upper coil fastening tool 9 are formed of iron, which is a magnetic material, the leakage magnetic flux leaking from the coil 7 causes the lower coil fastening. Flow through the tool 8 and the coil upper clamp 9, where stray losses occur. In particular, in the case where the frequency of the current flowing through the coil 7 is as high as 300 to 400 cycles, such as an oil-filled reactor used in the reactive power adjusting device, the leakage magnetic flux becomes extremely large, and the vibration and stray loss increase. If the stray loss increases, there is a problem that the temperature of the oil increases due to heat generation. Further, when the capacity of the transformer is increased, the relative leakage flux increases, and there is a problem that the influence of the leakage flux becomes larger.
[0007]
An object of the present invention is to provide a static induction electric device that can reduce stray loss.
[0008]
[Means for Solving the Problems]
The present invention provides an iron core including a plurality of legs and an upper yoke and a lower yoke connecting the plurality of legs, an upper core tightening tool for tightening the upper yoke, a lower core tightening tool for tightening the lower yoke, Between the coil attached to the legs of the iron core, the coil lower clamp fixed to the lower yoke and supporting the coil from below, and the coil lower clamp fixed to the upper yoke A stationary induction electric device main body including a coil upper tightening device for tightening a coil is attached to a bottom wall of a case, and the stationary induction electric device in which the inside of the case is filled with insulating oil is to be improved.
[0009]
In the present invention, at least one of the coil upper fastener and the coil lower fastener is formed of a wooden insulator. At least one of the upper core fastener and the lower core fastener includes a yoke tightening bolt that penetrates the yoke, and a yoke tightening nut that is screwed to the yoke tightening bolt to tighten the yoke. The wooden insulator is formed with a through hole through which the yoke tightening bolt penetrates, and the wooden insulator tightening nut is screwed to the yoke tightening bolt to fix the wooden insulator to the corresponding yoke.
[0010]
When yoke tightening insulating plates are arranged on both sides of the upper yoke and the lower yoke, and the corresponding yokes are tightened via the yoke tightening insulating plates with the yoke tightening nuts, the magnetic flux leakage from the coil causes the yoke tightening insulating plates to move. No stray loss occurs when passing. Therefore, it is possible to suppress an increase in the temperature of the oil in the case.
[0011]
[Action]
When at least one of the coil upper fastening tool and the coil lower fastening tool is formed of a wooden insulator as in the present invention, stray loss can be prevented even if leakage magnetic flux leaking from the coil passes through the wooden insulator. Therefore, an increase in the temperature of the oil in the case can be suppressed.
[0012]
The upper core tightening tool and the lower core tightening tool each include a yoke tightening bolt that penetrates the yoke, and a yoke tightening nut that is screwed to the yoke tightening bolt to tighten the yoke. When a through hole through which the tightening bolt penetrates is formed, and a wooden insulator tightening nut is screwed into the yoke tightening bolt and the wooden insulator is fixed to the corresponding yoke, a wooden insulator tightening different from the yoke tightening nut is performed. The nut can be tightened without damaging the wooden insulation and the yoke can be tightened with the required pressure.
[0013]
【Example】
1 to 4 show an embodiment of a stationary induction electric apparatus according to the present invention. This embodiment shows a case where the stationary induction electric device is an oil-filled reactor.
[0014]
In the stationary induction electric device of the present embodiment, each leg 1 of the iron core 4 of the stationary induction electric device main body 10 is constituted by a plurality of rims 22 stacked via an insulator 21. Rim fastening brackets 23 and 24 made of channel steel are arranged at both ends of the leg 1 in the vertical direction. Each rim 22 and each insulator 21 constituting each leg 1 are connected to the rim fastening metal 23, the upper yoke 3, each insulator 21, each rim 22, the lower yoke 2, and the rim. A rim fastening bolt 25 penetrating the fastening metal 24 in the up-down direction and a rim fastening nut 26 screwed to the rim fastening bolt 25 from outside the rim fastening metal 23, 24. An insulating sleeve 27 is fitted around the outer periphery of the rim fastening bolt 25 that penetrates each rim 22 and is insulated from each rim 22. An insulator 28 is also interposed between the upper and lower rim fastening brackets 23 and the rim 22 of the upper yoke 3. Similarly, an insulator 29 is interposed between the upper and lower rims 22 of the lower yoke 2 and the rim fastening metal 24.
[0015]
In the case of the present embodiment, the lower iron core tightening tool 5 includes a yoke tightening bolt 12 made of stainless steel penetrating the lower yoke 2, a yoke tightening nut 16 screwed to the yoke tightening bolt 12, and tightening the lower yoke 2. The yoke 2 includes a yoke fastening insulating plate 30, a washer 31, and a spring washer 32 interposed between the yoke 2 and the yoke fastening nut 16. An insulating sleeve 33 is fitted around the outer periphery of the yoke tightening bolt 12 penetrating the lower yoke 2 and is insulated from the lower yoke 2. Similarly, the upper core tightening tool 6 includes a stainless steel yoke tightening bolt 15 penetrating the upper yoke 3, a yoke tightening nut 16 screwed to the yoke tightening bolt 15 to tighten the upper yoke 3, and an upper yoke 3. A yoke fastening insulating plate 34, a washer 35, and a spring washer 36 interposed between the yoke fastening nut 16 are provided. An insulating sleeve 37 is fitted around the outer periphery of the yoke fastening bolt 15 that penetrates the upper yoke 3 and is insulated from the upper yoke 3.
[0016]
As described above, the lower iron core fastener 5 and the upper iron core fastener 6 of the present embodiment are configured without using the lower iron core fastener 11 and the upper iron fastener 14.
[0017]
Further, in this embodiment, the lower coil fastening tool 8 and the upper coil fastening tool 9 are formed of wooden insulators 8A and 9A made of reinforced wood.
[0018]
The wooden insulator 8A as the coil lower fastening member 8 is in contact with both sides of the lower yoke 2 via the yoke fastening insulating plate 30 described above. The wooden insulator 8 </ b> A is provided with a nut storage portion 38 for accommodating the washer 31, the spring washer 32, and the yoke tightening nut 16 corresponding to the existing locations, and a through hole 39 through which the yoke tightening bolt 12 penetrates. Have been. A wooden insulator tightening nut 41 is screwed through a washer 40 to the tip of the yoke tightening bolt 12 that has penetrated the through hole 39 to the outside, and the wooden insulator 8A is tightened. Fixed.
[0019]
Similarly, the wooden insulator 9 </ b> A as the coil upper fastening tool 9 is in contact with both sides of the upper yoke 3 via the above-described yoke fastening insulating plate 34. In the wooden insulator 9A, a nut storage portion 42 for accommodating the washer 35, the spring washer 36, and the yoke tightening nut 16 corresponding to the locations thereof, and a through hole 43 for passing the yoke tightening bolt 15 are continuously provided. Have been. A wooden insulator tightening nut 45 is screwed through a washer 44 to the tip of the yoke tightening bolt 15 that has penetrated the through hole 43 to the outside, and the wooden insulator 9A is tightened. Fixed.
[0020]
In particular, the wooden insulator 8A as the coil lower fastening member 8 has a length protruding below the lower end of the rim fastening member 24 so that the lower rim fastening member 24 floats from the bottom wall portion 47 of the case 46. It has a structure to have.
[0021]
The wooden insulator 8A and the rim fastening member 24 are connected by a bolt 48 and a nut 49.
[0022]
The coil 7 is fastened by a wooden insulator 8A as the coil lower fastening tool 8 and a wooden insulator 9A as the coil upper fastening tool 9 via coil holding insulators 17 and 18 that allow oil to flow. .
[0023]
As described above, when the coil lower fastening device 8 and the coil upper fastening device 9 are formed of the wooden insulators 8A and 9A, the leakage magnetic flux leaking from the coil 7 causes the coil lower fastening device 8 and the upper fastening device 9 of the coil 7 to move. Even if it passes, the occurrence of stray loss can be prevented. Therefore, an increase in the temperature of the oil in the case can be suppressed.
[0024]
When the lower coil fastening tool 8 and the upper coil fastening tool 9 are formed of the wooden insulators 8A and 9A, the vibration of the coil 7 can be attenuated by the wooden insulators 8A and 9A.
[0025]
Further, when the coil lower fastening member 8 made of the wooden insulator 8 </ b> A also serves as a stand for fixing the stationary induction electric device main body 10 to the bottom wall portion 47 of the case 46, the vibration of the coil 7 causes the bottom of the case 46. Transmission to the wall portion 47 can be suppressed.
[0026]
In particular, if only the coil lower fastening member 8 made of the wooden insulator 8A is in contact with the bottom wall portion 47 of the case 46 as in the present embodiment, the vibration of the coil 7 is caused by the wooden insulator 8A. The vibration is transmitted to the bottom wall portion 47 of the case 46 only through the base member 47, so that the vibration of the case 46 can be reliably suppressed.
[0027]
Further, as in the present embodiment, the stationary induction electric device is an oil-filled reactor, and the leg 1 of the iron core 4 is composed of a plurality of rims 22 stacked with an insulator 21 interposed therebetween. Rim fastening fittings 23 and 24 are arranged at both ends in the direction, respectively, and rim fastening bolts 25 and rim fastening fittings penetrating these rims 22, upper yoke 3, lower yoke 2, and rim fastening fittings 23 and 24. Each rim 22 is tightened by a rim tightening nut 26 screwed to the rim tightening bolt 25 from the outside of the rims 23 and 24, and the rim tightening metal fitting 24 located below the leg 1 is used as the coil lower tightening tool 8. When the bolts and nuts are used to fix the wooden insulator 8A, vibrations can be suppressed from the plurality of rims 22 stacked via the insulator 21.
[0028]
The iron cores of the yokes 2 and 3 are bonded between laminated steel sheets with an adhesive so that the laminated steel sheets are not separated. However, if vibration is transmitted to the iron cores of the yokes 2 and 3, the adhesive may be peeled off. Therefore, if the laminated steel sheets are tightened or restrained in the laminating direction by the yoke tightening bolts 12 and 15, the adhesive between the laminated steel sheets is peeled. Can be prevented.
[0029]
In the present embodiment, the yoke fastening insulating plates 30, 34 are arranged between the wooden insulators 8A, 9A and the yokes 2, 3, but if the laminated steel plates constituting the yokes 2, 3 are bonded with an adhesive. If not, it is necessary to use a steel plate instead of the yoke tightening insulating plates 30 and 34 because the yoke tightening insulating plates 30 and 34 need to be tightened considerably strongly. However, when an iron plate is used, the stray magnetic flux leaks from the coil 7 and passes through the iron plate, causing stray loss. Therefore, it is not desirable to place metal around the coil 7 as much as possible.
[0030]
Next, the reason why the yokes 2 and 3 are not tightened only through the wooden insulators 8A and 9A or the reason why the yokes 2 and 3 are tightened using the yoke tightening nuts 13 and 16 at positions covered by the wooden insulators 8A and 9A. explain.
[0031]
When reinforced wood is used as the wooden insulators 8A and 9A, the tightening strength of the reinforced wood is about 1 kg / cm ² , and the tightening force of the yokes 2 and 3 is 5 kg / cm ² at our company. Therefore, when the yokes 2 and 3 are tightened with a force of 5 kg / cm ² through the reinforced tree, the reinforced tree is damaged. Therefore, it is necessary to use the yoke tightening nuts 13 and 16 at positions covered by the wooden insulators 8A and 9A and tighten the yokes 2 and 3 with the yoke tightening nuts 13 and 16 without passing through the wooden insulators 8A and 9A. .
[0032]
Here, reinforced wood is obtained by laminating a plurality of plywoods with an adhesive and compressing them with strong force to increase mechanical strength and insulation. Usually, an insulating spacer is provided inside a transformer. Used for etc. The properties required for the reinforced wood are mechanical strength higher than a predetermined level and electrical insulation. The adhesive for bonding the plywood has a function of improving electrical insulation.
[0033]
Such reinforced wood is included in "wood insulation". The “wooden insulator” is formed using wood as a main material, and may be woodworked from ordinary wood, but reinforced wood is preferred.
[0034]
In the case of the present embodiment, the vibration generated in the coil 7 is reduced to approximately half by the rim tightening bolt 25 and the rim tightening nut 26, and the remaining wooden insulator 8A absorbs the remaining vibration.
[0035]
In the above embodiment, the stationary induction electric device main body 10 is supported by the bottom wall portion 47 of the case 46 via the wooden insulator 8A, but the present invention is not limited to this, and the stationary induction electric device is not limited thereto. As shown in FIG. 4, the main body 10 is connected to the wooden insulator 8A, the horizontal portion at the lower end of the rim fastening fitting 24 disposed therebelow, and the wooden insulator 50 disposed therebelow. The structure supported by the bottom wall portion 47 may be used.
[0036]
The embodiments of the present invention have been described above. The main aspects of the present invention disclosed in this specification are as follows.
[0037]
(1) An iron core including a plurality of legs formed of a plurality of rims stacked via an insulator, and an upper yoke and a lower yoke connecting the plurality of legs, and an upper core tightening the upper yoke. Tool, a lower iron core tightening tool for tightening the lower yoke, a coil mounted on a leg of the iron core, a coil lower tightening tool fixed to the lower yoke and supporting the coil from below, A coil lower clamp fixed to the lower yoke and supporting the coil from below, and a coil upper clamp fixed to the upper yoke and clamping the coil between the coil lower clamp. An oil-filled reactor in which a reactor body having a tool is attached to a bottom wall of a case, and the inside of the case is filled with insulating oil,
The coil upper clamp and the coil lower clamp are each made of a wooden insulator made of reinforced wood,
The upper core tightening tool and the lower core tightening tool each include a yoke tightening bolt that penetrates the yoke, and a yoke tightening nut that is screwed to the yoke tightening bolt and tightens the yoke.
The wooden insulator is formed with a through hole through which the yoke tightening bolt penetrates, and a wooden insulator tightening nut is screwed to the yoke tightening bolt, so that the wooden insulator is fixed to the corresponding yoke. An oil-filled reactor characterized by the following.
[0038]
(2) The oil-filled reactor according to (1), wherein a nut storage portion for storing the yoke tightening nut is continuously provided in the through hole formed in the wooden insulator.
[0039]
(3) The oil-filled reactor according to (1), wherein a tightening force of the wooden insulator tightening nut is smaller than a tightening force of the yoke tightening nut.
[0040]
(4) An iron core including three legs, an upper yoke and a lower yoke connecting the three legs, an upper core tightening tool for tightening the upper yoke, and a lower core tightening for tightening the lower yoke. Tool, three coils mounted on the legs of the iron core, and a pair of lower coils disposed on both sides of the lower yoke and fixed to the lower yoke to support the three coils from below. A stationary guide comprising a clamp and a pair of coil upper clamps disposed on both sides of the upper yoke and secured to the lower yoke to clamp the three coils between the coil lower clamp. In an oil-filled three-phase reactor in which an electric device body is attached to a bottom wall of a case and the case is filled with insulating oil,
At least one of the pair of coil upper fasteners and the pair of coil lower fasteners is formed of a wooden insulator,
The upper core fastening tool and the lower core fastening tool each include a yoke fastening bolt that penetrates the pair of yokes, and a yoke fastening nut that is screwed to the yoke fastening bolt to fasten a corresponding yoke,
The wooden insulator is formed with a through hole through which the yoke tightening bolt penetrates, and a wooden insulator tightening nut is screwed to the yoke tightening bolt, so that the wooden insulator is fixed to the corresponding yoke. An oil-filled three-phase reactor characterized by the following.
[0041]
【The invention's effect】
As described above, according to the stationary induction electric device of the present invention, at least one of the coil upper clamp and the coil lower clamp is formed of a wooden insulator, so that the leakage magnetic flux leaking from the coil causes the wooden insulator to change. The occurrence of stray loss can be prevented even when the oil passes through, so that the temperature of the oil in the case can be prevented from rising.
[0042]
The upper core tightening tool and the lower core tightening tool each include a yoke tightening bolt that penetrates the yoke, and a yoke tightening nut that is screwed to the yoke tightening bolt to tighten the yoke. When a through hole through which the tightening bolt penetrates is formed, and a wooden insulator tightening nut is screwed into the yoke tightening bolt and the wooden insulator is fixed to the corresponding yoke, a wooden insulator tightening different from the yoke tightening nut is performed. The nut can be tightened without damaging the wooden insulation and the yoke can be tightened with the required pressure.
[0043]
Further, when a yoke tightening insulating plate is arranged on both side surfaces of the upper yoke and the lower yoke, and a yoke tightening nut is configured to tighten the corresponding yoke via the yoke tightening insulating plate, the magnetic flux leaking from the coil causes the yoke tightening insulating plate. No stray loss occurs even through the plate, and from this point it is possible to suppress the temperature of the oil in the case from rising.
[Brief description of the drawings]
FIG. 1 is a front view of an embodiment of a stationary induction electric device according to the present invention.
FIG. 2 is a side view of the stationary induction electric device shown in FIG.
FIG. 3 is a sectional view taken along line XX of the stationary induction electric device shown in FIG.
FIG. 4 is a sectional view taken along line YY of FIG. 3;
FIG. 5 is a longitudinal sectional view of a main part of another example of the stationary induction electric device according to the present invention.
FIG. 6 is a perspective view of a conventional stationary induction electric device.
FIG. 7 is a sectional view taken along line ZZ of FIG. 6;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Leg 2 Lower yoke 3 Upper yoke 4 Iron core 5 Lower core fastener 6 Upper core fastener 7 Coil 8 Coil lower fastener 8A, 9A, 50 Wooden insulator 9 Coil upper fastener 10 Stationary induction electric equipment main body 12, 15 Yoke Tightening Bolts 13, 16 Yoke Tightening Nuts 17, 18 Coil Holding Insulator 21 Insulator 22 Rim 23, 24 Rim Tightening Bracket 25 Rim Tightening Bolt 26 Rim Tightening Nuts 27, 33, 37 Insulation Sleeve 28, 29 Insulator 30, 34 Yoke fastening insulating plates 31, 35 Washers 32, 36 Spring washers 38, 42 Nut storage portions 39, 43 Through holes 40, 44 Washers 41, 45 Wooden insulator fastening nuts 46 Case 47 Bottom wall 48 Bolts 49 Nuts

Claims (2)

An iron core including a plurality of legs, an upper yoke and a lower yoke connecting the plurality of legs, an upper core fastener for fastening the upper yoke, a lower core fastener for fastening the lower yoke, and the core A coil attached to the legs, a coil lower fastener fixed to the lower yoke and supporting the coil from below, and a coil lower fastener fixed to the upper yoke. A stationary induction electric device main body including a coil upper tightening tool for tightening the coil between the stationary induction electric device is attached to the bottom wall of the case, and the case is filled with insulating oil,
At least one of the coil upper fastener and the coil lower fastener is formed of a wooden insulator,
At least one of the upper core fastening tool and the lower core fastening tool includes a yoke fastening bolt penetrating the yoke, and a yoke fastening nut screwed to the yoke fastening bolt to fasten the yoke,
The wooden insulator is formed with a through hole through which the yoke tightening bolt penetrates, and a wooden insulator tightening nut is screwed to the yoke tightening bolt, so that the wooden insulator is fixed to the corresponding yoke. A stationary induction electric device characterized by the above-mentioned. A yoke fastening insulating plate is arranged on each side surface of the upper yoke and the lower yoke,
The stationary induction electric device according to claim 1, wherein the yoke tightening nut tightens the corresponding yoke via the yoke tightening insulating plate.

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