BRPI0904409A2 - stationary inductor - Google Patents

Abstract

INDUCTING APPLIANCE STACIUNARIU. The present invention relates to steel legs (1a) which are fastened by steel leg fastening elements (3) and unified by a plurality of steel leg fastening bands (4). Bars (1b) are arranged parallel to the rolling direction of these steel legs (1a), being held by yoke fasteners (5) with width identical to the minimum width of these yokes (lb), and are unified by a plurality of bands yoke fixing device (6). In addition, the steel legs (la), which are inserted into the winding (2), are connected, above and below the steel leg fixing elements (3), by square steel winding fixing tubes (7a), (7b) that are arranged above and below the winding (2), and their gripping is accomplished by adjusting the spacers (8) that are arranged between the winding (2) and the square steel tubes for securing the winding ( 7). These square steel tubes for securing the winding (7a), (7b) are made up of members with excellent rigidity and low mass.

Description

Descriptive Report of the Invention Patent for "STATIONARY INSTRUMENT".

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a stationary inductor apparatus and in particular to a stationary inductor apparatus in which construction for retaining the core and windings is improved.

2. Description of Related Art

In the medium capacity transformer class, there is currently a demand for a lighter stationary inductor device and less loss. Particularly in overseas markets, the mass of the stationary inductor interferes with transport costs and a favorable assessment of the stationary inductor in terms of loss and loss reduction could improve the competitive condition of the product.

A specific description of a fixture structure for a winding and laminated core in a stationary inductor apparatus employing a usual self-winding internal winding system will now be described with reference to Figures 1A and 1B. Specifically, as shown in Figure 1B, the transformer core is constructed of a laminated core 1 consisting of the rolling of a plurality of electric steel blades. The portions of this laminated core 1 that are inserted into the inside of the winding 2 consist of steel legs 1a, which are held by the steel leg fasteners 3 which are arranged with both end faces in the direction of rolling: the assembly is through the fastening produced by a plurality of steel leg fastening strips 4. Further, the yokes 1b, which connect a plurality of steel legs 1a and are arranged above and below the steel legs 1a, are fastened by means of the yoke fasteners 17 and unified by a plurality of yoke fastening bands 6.

In addition, yoke fasteners 17 securing yokes 1b above and below the foot of core 1a and which is responsible for securing winding 2 which is coaxially screwed to core foot 1a, are disposed on the outside of the lower and upper yokes 1b of winding 2 and are connected by the aforementioned core foot securing members 3; furthermore, the winding fastening blades 18 are arranged in a variety of locations, and the spacers 8 are arranged between the winding 2 and the winding fastening blades 18.

Since yoke fasteners 17 and winding fastening blades 18 which are attached to such yoke fasteners 17 are secured to the attachment points of the steel leg fasteners 3, they are attached. subjected to a rotational force by the take-up reaction of winding 2. To suppress this rotational force, the yoke clamping elements 17 which are disposed on both sides in the direction of the yoke lamination 1b are respectively joined by blades. connection 13 above the yokes 1b in the case of the upper yoke fasteners 17a disposed at the top of the winding, and lower of the yokes 1b in the case of the lower yoke fasteners 17b disposed in the winding background.

Due to the coupling provided by these coupling blades 13, yoke clamping elements 17 are identical to the height of the coupling blade configuration 13, i.e. the height to the edge of the maximum yoke width, and yoke fasteners 17 are constructed to cover the minimum width of yokes 1b so as to secure yokes 1b with uniform force by means of yoke fasteners 17. Consequently, it is The yoke clamping elements 17 of these two yoke clamping 1b and 2 clamping hold 2 functions must have a width variation from below the minimum width of the upper yoke to the top of the upper yoke for the upper yoke deflection member 17a and from above the minimum width of the lower yoke to the bottom section of the lower yoke for the fastener yoke from bottom 17b.

In addition, above the upper yoke fastener 17a, suspension wings 14 are mounted to suspend the internal structures constituted by, for example, the laminated core 1, the winding 2 and the retaining members for securing them. Suspension wings 14 are provided on the outer face of yokes 1b since yokes 1b which are weighted therewith are disposed within the yoke fastener 17a.

In the following, the laminated core and winding fastening structure in a stationary inductor apparatus employing a usual forced-winding internal cooling system will be described with reference to Figures 2A and 2B.

Members identical to those of the stationary inductor apparatus shown in Figures 1A and 1B are assigned identical reference symbols and their further description is omitted.

In this type of stationary inductor apparatus with forced cooling internal to the winding, as refrigerant ducts for forcibly cooling the inside of winding 2 from the outside of the tank15 of the stationary inductor, refrigerant pipes 16, secured by the yoke fastening elements. 17b are arranged on both side faces towards the core lamination of yokes 1b, which are unified by a plurality of yoke fastening bands 6. In addition, refrigerant tube holding blades 19 bottom yoke fasteners 17b are mounted and the aforementioned refrigerant pipes 16 are connected and supported on these refrigerant de-holding blades 19.

In addition, yoke fasteners 17 arranged above and below winding 2 are connected by steel leg fasteners 3 and bottom yoke fasteners 17b are inserted through insulating spacers 8 between refrigerant pipes 16 and the coil 2, so that a construction is obtained in which coil 2 is secured through the refrigerant pipes 16. In addition, the conduits for the inflow of refrigerant from the refrigerant pipes 16 to the coil 2 are provided at positions where winding oil 2 is introduced by drilling holes in the insulating spacers 8 and cooling tubes 16 mentioned above. The yoke fasteners 17 and refrigerant 16 are unified, and such a construction had a dual function of attaching to the yokes and securing the winding.

This type of construction is disclosed, for example, in Patent Application Open for Public Inspection No. JP Tokkai H. 6-176931 (hereinafter cited as Patent Reference 1).

However, there were the drawbacks reported below with respect to the winding and laminate core attachment construction in the conventional stationary inductor apparatus described above. Specifically, with respect to the yoke fasteners 17, which are in charge of the double function of attaching to the yokes and securing the winding as described above, to obtain the core fastening and the connection of the fastening fasteners. yoke 17 through the connecting blades 13 arranged above the yokes, the upper yoke fasteners 17a need to be larger than the width of the yoke fasteners from below the minimum width of the yoke. upper yoke to the top of the upper yo-ke, and the lower yoke fasteners 17b must be larger than the width of the yoke fasteners from above the minimum lower yoke width to the bottom of the lower yoke. In addition, to receive winding 2, a winding deflection blade 18 must be disposed on the yoke fasteners 17 and a grooved construction must be adopted in order to improve strength: consequently, the mass of the fastening fasteners "yo-ke" 17 gets bigger.

In addition, with the suspension wings 14 mounted on the opposite side face where the yoke fasteners 17 are secured by the steel leg mounting elements 3, in addition to the rotational force created by the reaction from winding 2, the force which is received suspension wings 14 as a result of the suspension, is generated on the yoke mounting elements 17, therefore it is necessary to increase the rigidity of the connecting blades 13 which are used to suppress this rotational force. This increases the weight of the connecting blades 13 and was a factor in increasing the internal mass of the transformer.

Further, with the upper yoke fastener 17 disposed adjacent to the winding below the minimum core width and a lower yoke fastener 17b disposed adjacent to the winding above the minimum core width, magnetic flux not has a connection in common with the inner winding and the outer winding, that is, the magnetic flux of the leakage, an amount inversely proportional to the square of the distance from winding 2, inserts these yoke fasteners 17: thus loss is generated.

Since the loss generated on these yoke fasteners 17 is approximately proportional to the square of the width of the yoke fasteners 17, the loss created by the leakage magnetic flux in the yoke fasteners 17 was raised by the fact that these yoke fastening elements were provided with a wide width to satisfy the yoke gripping and winding gripping functions.

SUMMARY OF THE INVENTION

The present invention was conceived with the intention of solving the drawbacks of the prior art, its purpose is to provide a stationary inductor apparatus that can reduce costs and improve electrical properties (or performance).

To achieve the above objective, the present invention is constructed as follows. Specifically, a stationary inductor apparatus comprising steel bars and legs composed of a laminated core, wherein a plurality of electric steel blades are laminated, wherein the winding is tangled around said steel legs and the steel legs. The aforementioned steel joints are joined to the steel leg fasteners by a plurality of steel leg fastening bands, characterized in that:

Yoke retaining members that unify the aforementioned yokes and the winding retaining members retaining the above-mentioned winding are separated and constituted, the aforementioned yoke retaining members are arranged parallel to the lamination direction of the earlier yokes. mentioned and constructed of metal members having a width which is almost identical to the minimum width of the aforementioned yokes; and

the aforementioned yokes and the aforementioned yoke retaining members are unified by a plurality of yoke attachment bands.

In addition, the present invention comprises:

a stationary inductor apparatus comprising steel bars and legs composed of a laminated core in which a plurality of electric steel blades are laminated, wherein the winding is threaded around the aforementioned steel legs, and the above-mentioned steel legs. mentioned are joined to the steel leg fasteners by a plurality of steel leg fastening bands, characterized in that:

yoke retaining members that unify the aforesaid yokes and the aforementioned winding retaining members are separated and respectively constituted;

the aforementioned yoke retaining members are arranged parallel to the lamination direction of the aforementioned yokes and constructed of insulating members having a width that is almost identical to the minimum width of the aforementioned yokes; and

aforementioned bars and the aforementioned yoke retaining members are unified by a plurality of yoke fastening bands.

With the present invention constructed as above, the endowment being a construction wherein the yokes are held by the yoke retaining members and, separately from these, the winding is held by the winding retaining members, the yoke retaining members "Yoke", which are provided for the sole purpose of attaching the "Yokes", can be produced in size as small as the minimum width of these "yo-kes". In addition, if metal members are employed as yoke retaining members, the thickness of their blades may be produced to a smaller size than conventional. In addition, if the insulating limbs were employed as the yoke retaining members, the mass could be reduced compared to the conventional, and it is possible to obtain a reduction in the losses produced by the magnetic leakage flux generated by the yoke retaining members.

With the present invention, thanks to the adoption of a construction in which the yoke gripping function performed by the yoke retaining members of the laminated core and the winding gripping function performed by the retaining limbs winding, are separated, it is possible to provide a stationary inductor apparatus in which a reduction in material costs and transport costs can be achieved due to weight reduction, and furthermore, electrical properties (or performances) can be improved. by reducing the amount of loss produced by the magnetic leakage stream.

BRIEF DESCRIPTION DQS DRAWINGS

Figure 1 is a view showing the construction of a conventional induction type self-cooling stationary inductor apparatus, Figure 1A is a front view and Figure 1B is a side view of this figure.

Figure 2 is a view showing the construction of a conventional type stationary induction apparatus with forced internal cooling to the winding, Figure 2A is the front view and Figure 2B is a side view of this figure.

Figure 3 is a view showing the construction of a first embodiment of a stationary conductive apparatus according to the present invention, Figure 3A is a front view and Figure 3B is a side view of this figure.

Figure 4 is a view showing the construction of a second embodiment of a stationary conductive apparatus according to the present invention, Figure 4A is a front view and Figure 4B is a side view of this figure.

Figure 5 is a view showing the construction of a third mode of a stationary conductive apparatus according to the present invention, Figure 5A is a front view and Figure 5B is a side view of that figure.

Figure 6 is a view showing a fourth mode construction of a stationary conductive apparatus according to the present invention, Figure 6A is a front view and Figure 6B is a side view of this figure.

Figure 7 is a view showing the construction of a fifth mode of a stationary conductive apparatus according to the present invention, Figure 7A is a front view and Figure 7B is a side view of this figure.

Figure 8 is a view showing the construction of a sixth mode of a stationary conductive apparatus according to the present invention, Figure 8A is a front view and Figure 8B is a side view of that figure.

Figure 9 is a view showing the construction of a seventh embodiment of a stationary conductive apparatus according to the present invention, Figure 9A is a front view and Figure 9B is a side view of that figure.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Embodiments of a stationary conductive apparatus according to the present invention are described below with respect to the drawings. Members identical to the members of the prior art constructions shown in Figure 1A, Figure 1B and Figure 2A, Figure 2B are assigned identical reference symbols and a further description is omitted.

(1) First Modality

(1-1) Construction

A characteristic feature of the present embodiment is that the two functions that were previously unified by the adoption of a construct in which the yokes 1b were held by the yoke fastener 5 (corresponding to the fastener member of yoke "of the claims) and the winding was secured by the square steel tube of the winding securing 7 (corresponding to the winding securing member of the claims) are separated in the present embodiment.

Specifically, in the present embodiment, as shown in Figure 3A and Figure 3B, the steel legs 1a are secured by means of the steel leg fasteners 3 and unified by a plurality of the steel leg fasteners 4. Still, yokes 1b are arranged parallel to the direction of lamination of these yokes 1b and secured by half yoke fasteners 5 equal in width to the minimum width of such bars 1b, and unified by a plurality of "yoke" banding bands. yoke "6.

Further, the winding 2 inserted into the steel legs 1a is secured by connecting the square steel winding fixing tubes 7a, 7 arranged above and below this wiring 2, above and below the core foot fastening elements 3 and adjusting the spacers 8 arranged between the square steel tubes for fixing winding 7 and winding 2.

It should be noted that these square steel coil clamping tubes 7a, 7b have small mass but excellent rigidity.

In addition, reinforcing blades are mounted on the square winding fastening tubes 7 as a countermeasure to the load generated on these square steel tubes 7 as a result of the winding fastening suspension. Specifically, the upper square steel clamping tubes 7a are connected by means of the upper square steel clamping members 9 and the lower square steel tubes of the clamping 7b are connected by the lower center members. connection of square steel pipe 10 to unify the internal structures and suppress the rotational force produced by the reaction to the hold of winding 2 and swinging in the vertical direction during transport.

(1-2) Action / EffectWith a stationary inductor according to this constructed pattern, a construction is adopted whereby yokes are secured by yoke fasteners 5 and the winding separately. 2 is secured by the square steel tubing fastening tubes 7, the size of the yoke fasteners 5, which have the sole purpose of attaching to the yokes 1b, may be reduced to the minimum width of each bar 1b . Also, if a metal blade is employed for yoke clamping elements 5, smaller than conventional blade thicknesses may be employed.

Thus, with this embodiment, the yo-kes 1b gripping functions by means of the yoke fastening elements 5 and winding gripping elements 2 are separated, resulting in mass reduction when compared to conventional construction, securing yokes 1b by means of yoke fasteners 5, which have substantially the same minimum width as such bars 1b, and securing winding 2 by means of steel tubes winding square 7 which have excellent rigidity but little mass. Moreover, when producing a thickness of small yoke fasteners 5, the loss produced by the leakage magnetic flux generated in the yoke fasteners 5 can be reduced so that costs such as material costs and transportation costs can be eliminated thanks to weight reduction compared to conventional, and it is possible to provide a stationary inductor with better electrical properties (or performance).

(2) Second Modality

This embodiment is a modification of the above first embodiment, wherein the insulating yoke fastening blades 11 made of insulating material are employed in place of the yoke securing elements used in the first embodiment. Specifically, as shown in Figure 4A and Figure 4B, as well as the retaining limbs for the yokes 1b, the insulating yoke clamping blades 11 are employed to remain arranged parallel to the lamination direction of the yokes. yokes "1b and aa are substantially the same width as the minimum width of yo-kes 1b; These yoke clamping insulators 11 are unified to yo-kes 1b by clamping using a plurality of yoke clamping bands 6.

With a embodiment constructed in this way, by performing fastening to the yokes 1b using the yo-ke fasteners 11 in place of the yoke fasteners 5, the mass can be reduced and it is possible to obtain a reduction in the magnetic flux loss generated in the yoke fasteners. As a result, the pressure produced on the yoke retaining members is therefore eliminated and it is possible to provide a stationary inducing apparatus that has low mass and better electrical properties (or performance).

(3) Third Modality

(3-1) Construction

This modality is a modification of the above second modality. In this embodiment, the yoke clamping insulating blade 11 shown in the second embodiment is employed as the clamping member for yoke retainers 1b and this yoke clamping insulator 11 is unified to the yo-kes! b by fastening using a plurality of yoke fastening bands 6.

In contrast, winding 2 is secured by means of an L-shaped winding fastening blade 12, as shown in Figure 5A and Figure 5B. Specifically, the L-shaped winding fixing blades 12, which are formed by welding the second metal blades 12b to retain the winding to the first metal blades 12a, intersecting with them, are arranged on both sides of the lower and lower yokes. upper 1b arranged on both sides of upper and lower yokes 1b. These L-shaped winding fixing blades 12 are connected by the steel leg fastening elements 3, and the spacers 8 are disposed between these L-shaped winding fixing blades 12 and winding 2; winding 2 is therefore clamped by these elements. It should be noted that the rotational force resulting from the reaction to the grasp of winding 2 and the swing in the vertical direction during transport are produced on the fastening blades of the L-shaped winding 12 mentioned. above, therefore, as a countermeasure, the L-shaped winding 12 securing blades disposed on both side faces of the upper and lower yokes are respectively joined by the connecting blades 13.

(3-2) Action / effect

With the stationary inductor apparatus in accordance with this fashion thus constructed, as a result of the fact that the fixing of the yo-kes 1 b is carried out by the use of yoke fixing insulators 11, the mas-sa is smaller and the effect of the magnetic leakage flux is smaller than in the case where the fixation is performed using the yoke fasteners. Also, when, as in the first embodiment, the square steel tubes for fixing the winding are employed to retain the winding, the space for making the internal connection scheme is reduced by the size corresponding to the square steel tubes. However, since the L-shaped winding fastening blades 12 of this embodiment have an open structure, the space for making the internal connection diagram is increased.

With the present embodiment, securing the yokes by means of two yoke fastening ties and securing the winding by means of the L-shaped winding securing blades, expenses such as material costs and costs With transport, they can be cut thanks to weight reduction and improved electrical properties, making it possible to provide a stationary inductor apparatus in which the wiring diagram of the internal structure can be assembled with ease and easy handling.

(4) Fourth Modality

(4-1) Construction

This modality is a modification of the first and second modalities. As shown in Figure 6A and Figure 6B, the yoke fastening insulating blades 11 shown in the second embodiment are employed as the yoke retaining members 1b, and these yoke securing insulators 11 are unified to the yokes 1 b by fastening a plurality of yoke fasteners 6. In addition, in the winding 2 where the steel legs 1a are inserted, the steel legs are connected above and below by the fasteners 3, the tubes square steel clamps 7 are provided above and below that winding 2 and spacers 8 are arranged between the square steel clamps of winding 7 and winding 2, so that gripping can be obtained by adjusting them .

It is noted that in this embodiment the square steel deflection tubes of winding 7a which are disposed at the top of winding 2 are misaligned in the opposite direction (upward in Figure) to the winding near the center of the upper yokes 1b.

(4-2) Action / effect

With the inductive apparatus stationary according to the presently constructed embodiment, since the square steel upper winding fixing pipes 7a are not responsible for the function of attaching to the yokes 1b of the laminated core, these square steel pipes of the upper winding 7a may be de-salted in the opposite direction to the winding from the center of the yokes 1b: the volume of the magnetic leakage flux that penetrates the square winding pipes of Attachment of the upper winding 7a from the winding is then reduced. As a result, the effect of the magnetic flux of the leakage on the square steel pipes of the upper winding fixing 7 becomes small, allowing the loss that could be generated to be suppressed and allowing the supply of a stationary inductor with its electrical properties ( or performance) are also improved.

(5) Fifth Modality

This modality is a modification of the above fourth mode. As shown in Figure 7A and Figure 7B, the square-bending steel tubes of winding 7b which are arranged below winding 2 are arranged to be misaligned in the opposite direction (downward in the drawing) to the winding from the center of the " lower yokes. The rest of the construction is identical to the case of the fourth mode described above.

With the inductive apparatus stationary according to the presently constructed embodiment, since the lower winding square steel tubes 7b are not responsible for securing the yokes of the laminated core, these winding square steel tubes 7b can be arranged misaligned in the opposite direction to the winding from the center of the yokes: the volume of the magnetic leakage flux that penetrates the lower winding square steel fixing tubes 7b from the winding is reduced. As a result, the effect of the magnetic flux of the leakage on the lower winding square steel pipe 7b becomes small, thus allowing the loss suppression that could then be generated and allowing the supply of a stationary inductor apparatus whose properties electric power are further improved.

(6) Sixth Modality

(6-1) Construction

This modality is a modification of the above fourth and fifth modalities. As shown in Figure 8A and Figure 8B, the upper winding square steel pipes 7a which are arranged above the winding 2 are arranged to be misaligned in the opposite direction (vertically in the drawing) to the winding from center d upper bars. In addition, the lower-winding square steel clamping tubes 7b which are arranged below the winding 2 are arranged in a misaligned downward direction from the center of the lower yokes.

In addition, in this embodiment, the suspension wings 14, intended to suspend all internal structures, are provided on the side face on the yoke side 1b of the upper winding square steel tubes 7a, in the position where the steel leg fasteners 3 are attached to the lower and upper winding square steel fastener pipes 7a, 7b mentioned above.

(6-2) Action / effect

With the inductive apparatus stationary according to the presently constructed mode, thanks to the mounting of the suspension wings 14 in the position where the steel leg fasteners 3 are attached to the upper winding square steel pipes 7a, no Bending tension is generated during suspension with respect to the longitudinal direction of the upper steel square clamping tubes 7a. Further, by the fact that both the connections of the steel leg clamping members 3 to the upper winding square steel clamping tubes 7a and the mounting of the suspension wings 14 are performed on the side faces on the yoke side of the clamps. square steel pipe for fixing the winding, it is possible to suppress the generation of bending stress in relation to the short side direction of the square steel pipe for fixing the winding during suspension.

This makes it possible to reduce the extent of mounting of the reinforcing members on the square steel tubes of the bearing retainer to retain the winding and / or the suspension of the internal structures, and it is possible to provide a stationary inductor apparatus in which the dough can be be reduced and costs reduced.

(7) Seventh Modality

(7-1) Construction

This embodiment is a modification of the second embodiment.

As shown in Figure 9A and Figure 9B, the yo-ke securing sheet 11 as shown in the second embodiment is employed as the yoke securing member 1b and this yoke securing insulator 11 is attached to the yoke. yokes "1b by clamping a plurality of yoke clamping bands 6.

Also, as shown in Figure 9A, in this embodiment, the refrigerant pipes 16, which transmit the refrigerant from the external part of the tank 15 of the stationary inductor apparatus, are connected to the square steel lower winding fixing pipes 7b so that lower winding square steel fixing tubes 7b provide flow paths for the refrigerant. In addition, holes are drilled within the lower winding square steel fixing tubes 7b and the insulating spacers 8 which are inserted between the winding 2 and the lower winding square steel fixing tubes 7b so that Refrigerant from the outside of the tank can be introduced into the winding 2.

(7-2) Action / effect

With the conductive apparatus stationary according to this embodiment constructed as above, the lower winding square steel tubes 7b are responsible for securing winding 2 and as paths for refrigerant flow to forcefully cool the interior of the winding . Consequently, the sections of the forced cooling pipe employed in the conventional stationary inductor apparatus shown in Figure 2A and Figure 2B can be dispensed with, which makes it possible to provide a lightweight, low cost stationary inductor apparatus.

Claims (9)

1. Stationary inductor apparatus comprising: steel bars and legs composed of a laminated core in which a plurality of electric steel blades are laminated, in which a winding is wrapped around the steel legs and the steel legs joined to the fasteners. of the steel leg by a plurality of core foot securing bands, characterized in that: the yoke retaining members that unite to said yokes and the winding retaining members retaining said winding are constituted by respectively separately, said yoke retaining members are arranged parallel to the direction of lamination of said yokes and are constructed of metal members having a width which is approximately identical to the minimum width of said yokes; said yokes and said yoke retaining members are joined by a plurality of yoke attachment bands. 2. Stationary inductor apparatus comprising: steel bars and legs composed of a laminated core in which a plurality of electric steel blades are laminated, wherein a winding is wrapped around said steel legs, and said steel legs. are joined to the steel leg fasteners by a plurality of steel leg fastening bands, characterized by the fact that: the yoke retaining members that unite to said yokes, and the winding retaining members retaining the said winding are constituted separately respectively, said yoke retaining members are arranged parallel to the direction of lamination of said yokes and are constructed of insulating members having a width substantially identical to the minimum width of said yokes. yokes; said yokes and said yoke retaining members are joined by a plurality of yoke attachment bands. Stationary inductor apparatus according to claim 1 or claim 2, characterized in that said coil retaining members are constituted by square steel tubes, and the gripping of said coil is obtained by the connection of the upper and square steel tubes. above and below said steel leg fasteners, said square steel tubes being arranged above and below said coil, and spacers between said square steel tubes and said coil. Stationary inductor apparatus according to claim 2, characterized in that said winding retaining members are constituted by L-shaped winding fixing blades obtained by connecting the first metal blades disposed on both sides of the yokes. lower and upper than the second metal blades crossing said first blades, said L-shaped winding attachment blades being disposed on both sides of the lower and upper yokes, with the spacers being disposed between said blades. L-shaped winding securing blades and said winding, said winding is secured by attaching said L-shaped upper and lower winding fixing blades above and below said steel leg fastening members. Stationary inductor apparatus according to claim 3, characterized in that said square steel tubes are arranged in misalignment contrary to said winding from the center of said upper yokes, and the spacers are inserted between said winding and said square steel tubes. Stationary inductor apparatus according to claim 3, characterized in that said square steel tubes are arranged in misalignment contrary to said winding from the center of said lower yokes, and spacers are inserted between the said winding and the square steel dithostubes. Stationary inducing apparatus according to claim 3, characterized in that the upper retaining members of the winding which are arranged on both side faces of said upper yokes are connected by the upper connecting members, and the upper limbs. Lower winding retainers which are disposed on both side faces of the lower yokes are joined by the lower connecting members. Stationary inductor apparatus according to claim 3, characterized in that the suspension wings are provided on the yoke side faces of said coil retaining members in positions where said steel leg fasteners are provided. are attached and fixed to said retaining members of the winding. Stationary inducing apparatus according to claim 3, characterized in that said lower square steel pipes are connected to pipes carrying refrigerant from the outside to said winding and holes constituting the refrigerant ducts. formed in prescribed positions of said spacers and said lower square steel tubes, so that said lower square steel tubes act as refrigerant conduits.