CN205452026U - Superconductive controllable reactor - Google Patents

Abstract

The embodiment of the utility model discloses superconductive controllable reactor, include primary winding, the superconductive winding of secondary, iron core, cryogenic cooling container, cooling tube, feed liquor pipe, drain pipe and do not have magnetism strutting arrangement. The cooling tube includes cooling tube and lower cooling tube, and the feed liquor pipe is linked together with lower cooling tube, and the drain pipe is linked together with last cooling tube, and the feed liquor is managed and the drain pipe extends the cryogenic cooling container respectively, going up the cooling tube and setting up in the one end of the superconductive winding of secondary, and be located the open end of cryogenic cooling container, lower cooling tube sets up in the other end of the superconductive winding of secondary, has seted up a plurality of cooling holes under and on the cooling tube towards the last cooling tube of the superconductive winding of secondary one side. The utility model discloses a reactor sets up the cooling that the superconductive winding of secondary was realized to the cooling tube through tip about the superconductive winding of secondary, realizes coolant's circulation flow and utilization to in time shift the superconductive winding of the secondary heat of end coil AC loss production from top to bottom.

Description

A kind of superconductive controllable reactor

Technical field

This utility model relates to reactor technical field, particularly relates to a kind of superconductive controllable reactor.

Background technology

Reactor is a kind of important electric device, is widely used in limiting power-frequency overvoltage, eliminating electromotor self-excitation, Suppressing Switching Overvoltage, limiting short-circuit current and flat ripple etc. in power system.Along with the development of power system, more and more higher to the performance requirement of reactor, wish that the reactance value of reactor can regulate in real time or control in many occasions.

In prior art, the coil of super conducting electric reactor uses superconductor to carry out coiling, and runs under cryogenic.Conventional superconductive controllable reactor mainly includes routine work winding, some secondary superconduction windings, iron core and low-temperature (low temperature) vessel, routine work winding and secondary superconduction winding are socketed in iron core column periphery respectively, secondary superconduction winding is positioned in low-temperature (low temperature) vessel, is lowered the temperature secondary superconduction winding by low-temperature (low temperature) vessel.

But, the coil at secondary superconduction winding two ends is significantly higher than, due to the heat that A.C.power loss produces, the heat that other position coils of winding produce so that secondary superconduction winding two ends temperature rise is relatively big, easily causes reactor to damage.

Utility model content

This utility model embodiment provides a kind of superconductive controllable reactor, it is significantly higher than, due to the heat that A.C.power loss produces, the heat that other position coils of winding produce with the coil at secondary superconduction winding two ends in solution prior art, make secondary superconduction winding two ends temperature rise relatively big, easily cause the problem that reactor is damaged.

In order to solve above-mentioned technical problem, this utility model embodiment discloses following technical scheme:

The utility model discloses a kind of superconductive controllable reactor, including: winding, secondary superconduction winding, iron core, sub-cooled container, cooling tube, feed tube, drain pipe and without magnetic support means；

Described iron core includes that iron core frame and iron core column, described iron core column are vertically installed in inside described iron core frame；

Described secondary superconduction winding includes the first superconduction winding and the second superconduction winding, first superconduction winding described in described sub-cooled container pack and the second superconduction winding and described first superconduction winding are positioned at the inner side of described second superconduction winding, a described winding is positioned at the periphery of described sub-cooled container, and described sub-cooled container set is connected to described iron core column periphery, described first superconduction winding, the second superconduction winding and the axis of a winding and the axis of described iron core column are same straight line；

Described cooling tube includes cooling tube and lower cooling tube, and described feed tube is connected with described lower cooling tube, and described drain pipe is connected with described upper cooling tube, and described feed tube and drain pipe each extend over out described sub-cooled container；Described upper cooling tube is arranged at one end of described secondary superconduction winding and is positioned at the opening of described sub-cooled container, described lower cooling tube is arranged at the other end of described secondary superconduction winding, offers multiple Cooling Holes on the described upper cooling tube and lower cooling tube of described secondary superconduction winding side；

Being respectively provided with the described secondary superconduction winding in location and the locating slot of cooling tube on the supporting surface of described support means without magnetic, described support means without magnetic is correspondingly arranged in the two ends of described secondary superconduction winding.

Preferably, it is characterised in that described upper cooling tube includes on first cooling tube on cooling tube and second, and described lower cooling tube includes first time cooling tube and second time cooling tube；Wherein,

On described first, on cooling tube and second, cooling tube is respectively arranged at described first superconduction winding and the outside of the second superconduction winding upper end, described first time cooling tube and second time cooling tube are respectively arranged at described first superconduction winding and the outside of the second superconduction winding lower end, and have multiple hole towards described secondary superconduction winding side on described cooling tube.

Preferably, described support means without magnetic being additionally provided with circulation groove, described circulation groove is arranged on the non-supported face of described support means without magnetic.

Preferably, described sub-cooled container is set to composite Non-magnetic dewar, and described Dewar includes that watt body and FE Tiler, secondary superconduction winding are arranged in described watt body；

Described FE Tiler includes that basin body FE Tiler and plane tile lid, described basin body FE Tiler mate with the opening of described sub-cooled container, and described flat board FE Tiler is arranged on described basin body FE Tiler, for covering basin body FE Tiler；

Described feed tube and drain pipe extend described sub-cooled container by described basin body FE Tiler and plane tile lid.

Preferably, described iron core frame is provided with the hole, location mated with described feed tube and drain pipe, described feed tube and drain pipe and extends described iron core by hole, described location；

Hole, described location is arranged along described iron core frame length direction and the center of circle in hole, described location is located on the same line；

Described iron core frame is set to the amorphous magnetic alloy thin slice of high permeability, high resistivity.

Preferably, being provided with annular magnet in the space formed between described basin body FE Tiler and described flat board FE Tiler, described annular magnet is set to the amorphous magnetic alloy thin slice of multiple mutually insulated and is formed by stacking.

Preferably, it is provided with between a described winding inner ring surface and described sub-cooled container outer ring surface and shields circlewise.

Preferably, described secondary superconduction winding is set to multiple disk-type winding cascaded structure.

Preferably, described iron core frame and iron core column are formed by stacking by the amorphous magnetic alloy thin slice of multiple mutually insulateds.

From above technical scheme, the superconductive controllable reactor that this utility model embodiment provides is based on vacuum technique, cryogenic technique, superconductor technology, insulation technology, electromagnetic technique and material technology combine, based on conventional reactor, with without magnetic, insulation, low temperature resistant composite material vessel realizes the splendid attire of superconduction winding and cooling medium thereof, and the upper and lower end parts at secondary superconduction winding arranges cooling tube, feed tube connects with lower cooling tube, drain pipe connects with upper tubing, and on cooling tube, offer Cooling Holes, achieve circulation and the utilization of cooling medium, medium bigger for secondary superconduction winding two ends temperature rise is shifted during circulation by cooling medium in time.The annular magnet of high permeability, high resistivity is set on secondary superconduction winding top simultaneously, reduces the magnetic field degree of divergence at secondary superconduction winding upper and lower side, also reduce the heat that secondary superconduction winding produces due to A.C.power loss.

Accompanying drawing explanation

In order to be illustrated more clearly that this utility model embodiment or technical scheme of the prior art, the accompanying drawing used required in embodiment or description of the prior art will be briefly described below, apparently, for those of ordinary skills, on the premise of not paying creative work, it is also possible to obtain other accompanying drawing according to these accompanying drawings.

A kind of superconductive controllable reactor cross-sectional view that Fig. 1 provides for this utility model embodiment；

A kind of sub-cooled structure of container schematic diagram that Fig. 2 provides for this utility model embodiment；

A kind of superconductive controllable reactor decomposition texture schematic diagram that Fig. 3 provides for this utility model embodiment；

A kind of core structure schematic diagram that Fig. 4 provides for this utility model embodiment；

In Fig. 1-Fig. 4, symbol represents:

Winding of 1-, bis-superconduction windings of 2-, 21-the first superconduction winding, 22-the second superconduction winding, 3-iron core, 31-iron core frame, 311-positions hole, 32-iron core column, 4-cooling tube, cooling tube on 41-first, cooling tube on 42-second, first time cooling tube of 43-, second time cooling tube of 44-, 5-feed tube, 6-drain pipe, 7-is without magnetic support means, 71-locating slot, 72-circulation groove, 8-sub-cooled container, 81-basin body FE Tiler, 82-flat board FE Tiler, 9-shields circlewise, 10-annular magnet.

Detailed description of the invention

This utility model embodiment provides a kind of superconductive controllable reactor, for the technical scheme making those skilled in the art be more fully understood that in this utility model, below in conjunction with the accompanying drawing in this utility model embodiment, technical scheme in this utility model embodiment is clearly and completely described, obviously, described embodiment is only a part of embodiment of this utility model rather than whole embodiments.Based on the embodiment in this utility model, the every other embodiment that those of ordinary skill in the art are obtained under not making creative work premise, all should belong to the scope of this utility model protection.

In order to make those skilled in the art be more fully understood that this utility model scheme, the utility model is described in further detail with embodiment below in conjunction with the accompanying drawings.

See Fig. 1, a kind of superconductive controllable reactor cross-sectional view provided for this utility model embodiment, see Fig. 2, a kind of sub-cooled structure of container schematic diagram provided for this utility model embodiment.

As it can be seen, the reactor that this utility model embodiment provides includes winding 1, secondary superconduction winding 2, iron core 3, sub-cooled container 8, cooling tube 4, feed tube 5, drain pipe 6 and without magnetic support means 7.Wherein, iron core 3 includes that iron core frame 31 and iron core column 32, iron core frame 31 are rectangle iron core frame, is vertically arranged iron core column 32 in iron core frame 31, and iron core column 32 is cylinder-shaped iron core post 32.Additionally, iron core frame 31 and iron core column 32 are formed by the amorphous magnetic alloy thin slice superposition of multiple mutually insulateds, amorphous magnetic alloy thin slice is high permeability, high resistivity material, effectively reduce eddy current and the Joule heat of generation thereof that iron core 3 produces, simultaneously, high permeability, the amorphous magnetic alloy thin slice of high resistivity substitute conventional stalloy and make iron core 3, and iron core column 32 enhances the magnetic field of reactor center, decreases the impact of external magnetic field two end-coils upper and lower on superconduction winding.

Secondary superconduction winding 2 includes the first superconduction winding 21 and the second superconduction winding 22, sub-cooled container 8 wraps up the first superconduction winding 21 and the second superconduction winding 22, and first superconduction winding 21 be positioned at the inner side of the second superconduction winding 22, winding 1 is positioned at the periphery of sub-cooled container 8, and sub-cooled container 8 is socketed on iron core column 32 periphery, first superconduction winding the 21, second superconduction winding 22 and the axis of a winding 1 and the axis of iron core column 32 is same straight line.Sub-cooled container 8 is provided with without magnetic, insulation, low temperature resistant composite Non-magnetic dewar, and composite Non-magnetic dewar includes watt body and FE Tiler, and wherein a watt body is set to double-deck watt body.

In the present embodiment, composite Non-magnetic dewar is overlooked and is seen as concentric ring structure, and section is U-shape structure, and U-shape structure is a watt body, and wherein secondary superconduction winding 2 is positioned at its U-shape structure.FE Tiler includes basin body FE Tiler 81 and plane tile lid 82, and basin body FE Tiler 81 mates with the opening of sub-cooled container 8, and basin body FE Tiler 81 covers the opening of sub-cooled container 8 and makes formation confined space in watt body, is coated with plane tile lid 82 on basin body FE Tiler 81.Said structure is a kind of embodiment of sub-cooled container 8, and should not be taken as the restriction of this utility model scope, and those skilled in the art may select other forms according to practical situation, within it all should fall into protection domain of the present utility model.

First superconduction winding 21 and the second superconduction winding 22 are placed in the confined space of watt body, and wherein the first superconduction winding 21 is positioned at the inner side of the second superconduction winding 22.Additionally, winding 1 is positioned at the periphery of sub-cooled container 8, first superconduction winding the 21, second superconduction winding 22 and the axis of a winding 1 are same straight line with the axis of iron core column 32, and having gap between each winding, the first superconduction winding 21 and the second superconduction winding 22 are all fixed by winding skeleton.It is placed with low-temperature cooling media in the confined space of watt body, and the confined space between double-deck watt body is set to vacuum sealing space, and the first superconduction winding 21 and the second superconduction winding 22 are submerged in the low-temperature cooling media in the sub-cooled container that internal layer watt body is wrapped to form.

Cooling tube 4 includes cooling tube and lower cooling tube, wherein go up cooling tube be arranged at one end of secondary superconduction winding 2 and be positioned at the opening of sub-cooled container, lower cooling tube is arranged at the other end of secondary superconduction winding 2, it addition, offer multiple Cooling Holes on the upper cooling tube and lower cooling tube of secondary superconduction winding 2 side.Upper cooling tube is connected with drain pipe 6, and lower cooling tube is connected with feed tube 5, and drain pipe 6 and feed tube 5 extend sub-cooled container by FE Tiler.Low-temperature cooling media forms circulation by feed tube 5, lower cooling tube, upper cooling tube, Cooling Holes and drain pipe 6.Cooling medium is entered in lower cooling tube by inlet opening, and enter in the confined space that internal layer watt body is wrapped to form by the Cooling Holes on lower cooling tube, low-temperature cooling media flows in watt body and reaches to cool down the effect of secondary superconduction winding 2, the low-temperature cooling media that temperature uprises is entered by the Cooling Holes of upper end after going up in cooling tube, by drain pipe 6, high-temperature medium is extracted out, then supplemented again through feed tube 5 by refrigeration machine refrigeration, thus reach the effect recycled.

In order to make secondary superconduction winding 2 and cooling tube 4 in low-temperature cooling media more firm, the invention also discloses for supporting firm secondary superconduction winding 2 and the support means without magnetic 7 of cooling tube 4, be set to without magnetic, insulation, low temperature resistant composite without magnetic support means 7.Without being provided with location secondary superconduction winding 2 and the locating slot 71 of cooling tube 4 in magnetic support means 7, locating slot 71 mates with secondary superconduction winding 2 and cooling tube 4 respectively.

Owing to the magnetic direction of secondary superconduction winding 2 upper and lower side changes greatly, the coil heating being in secondary superconduction winding 2 upper and lower side is serious, thus cause cooling down power and increase, by arranging annular magnet 10 in the space between basin body FE Tiler 81 and plane tile lid 82, wherein annular magnet 10 is formed by stacking by the amorphous magnetic alloy thin slice of high permeability, high resistivity, annular magnet 10 can reduce the magnetic field degree of divergence in secondary superconduction winding 2 upper and lower end parts, also reduces the heat that secondary superconduction winding 2 produces due to A.C.power loss.

Being provided with between winding 1 inner ring surface and sub-cooled container 8 outer ring surface and shield 9 circlewise, secondary superconduction winding 2 is in series by multiple disk-type windings, by Guan Bi or disconnection secondary superconduction winding 2 loop, it is achieved the regulation of reactor reactance value.

See Fig. 3, a kind of superconductive controllable reactor decomposition texture schematic diagram provided for this utility model embodiment.More firm in order to make secondary superconduction winding 2 position, it is respectively provided with without magnetic support means 7 at the two ends up and down of secondary superconduction winding 2, the support means without magnetic 7 that the present embodiment provides is symmetricly set in the two ends of secondary superconduction winding 2.Being provided with locating slot 71 and the locating slot 71 of location cooling tube of location secondary superconduction winding 2 on the supporting surface of support means without magnetic 7, wherein supporting surface refers in the one side without directly contacting with secondary superconduction winding 2 in magnetic support means 7.

Without being additionally provided with circulation groove 72 on the non-supported face of magnetic support means 7, the support means without magnetic 7 at two ends all contacts with upper plane and the bottom surface of sub-cooled container 8 up and down, circulation groove 72 can facilitate medium to circulate at high liquid level (HLL) hoop, meanwhile, cooling medium also can be flowed by circulation groove 72 hoop at minimum level.

Cooling tube 4 in this utility model embodiment includes cooling tube and lower cooling tube, wherein go up cooling tube and include on first cooling tube 42 on cooling tube 41 and second, on first, on cooling tube 41 and second, cooling tube 42 is respectively arranged at the first superconduction winding 21 and the outside of the second superconduction winding 22 upper end, namely outer rim side of superconduction winding.Lower cooling tube includes that first time cooling tube 43 and second time cooling tube 44, first time cooling tube 43 and second time cooling tube 44 are respectively arranged at the first superconduction winding 21 and outside of the second superconduction winding 22 lower end.Wherein first time cooling tube 43 is connected with feed tube 5 respectively with second time cooling tube 44, and on first, cooling tube 41 is connected with drain pipe 6 respectively with cooling tube on second 42.It is respectively provided with cooling tube 4 in the outside of the first superconduction winding 21 and the two ends up and down of the second superconduction winding 22, and the side to secondary superconduction winding 2 is evenly arranged with multiple Cooling Holes on cooling tube 4, the heat that secondary superconduction winding about 2 two ends produce due to higher A.C.power loss can be taken away by the cooling medium of turnover cooling tube 4.

Drain pipe 6 and feed tube 5 extend sub-cooled container 8 by basin body FE Tiler 81 and plane tile lid 82, and on iron core frame 31, it is provided with the hole, location 311 mated with feed tube 5 and drain pipe 6, feed tube 5 and drain pipe 6 extend iron core frame 31 by hole 311, location, the lower cooling tube of feed tube 5 connection, directly can supplement cooling medium in sub-cooled container 8, cooling medium after temperature rise is exported to refrigeration machine after refrigeration by drain pipe 6, then supplements cooling medium in sub-cooled container 8 by feed tube 5.

As shown in Figure 4, a kind of core structure schematic diagram provided for this utility model embodiment.

Hole 311, location is arranged on the length direction of iron core frame 31, and the center of circle positioning hole 311 is located on the same line, and reduces feed tube 5 and drain pipe 6 passes the impact that reactor performance is caused by iron core frame 31.

Cooling tube 4, feed tube 5 and drain pipe 6 are set to be disposed as without magnetic, insulation, low temperature resistant composite, the cooling medium temperature rise being further exacerbated by around secondary superconduction winding 2 top and the bottom according to metal tube, superconduction winding is probably due to cool down insufficient quenching.

As seen from the above-described embodiment, operate in secondary superconduction winding 2 under AC magnetic field and can produce heat due to A.C.power loss, the magnetic direction conversion of winding 2 upper and lower end parts of secondary superconduction simultaneously is relatively big, and the coil heating being in secondary superconduction winding 2 upper and lower end parts is serious, thus it is bigger to cause cooling down power.Reactor disclosed in this utility model realizes the cooling of secondary superconduction winding 2 by arranging cooling tube 4 in secondary superconduction winding 2 upper and lower end parts, cooling tube 4 connects with feed tube 5 and drain pipe 6 respectively, realize circulating and utilizing of cooling medium, thus reduce the magnetic field the degree of heat in secondary superconduction winding 2 upper and lower end parts, also reduce the heat that superconducting coil produces due to A.C.power loss.Additionally, secondary superconduction winding 2 is both placed in sub-cooled container 8, and in the sub-cooled container that the internal layer watt body of sub-cooled container 8 is wrapped to form, fill low-temperature cooling media, in sub-cooled container 8, cooling medium is constantly supplemented by feed tube 5, cooling tube 4 and drain pipe 6, and again add in sub-cooled container 8 after extracting the cooling medium of temperature rising out refrigeration, thus realize circulating and utilizing of cooling medium.

In reactor disclosed in this utility model, iron core frame 31, iron core column 32 and annular magnet 10 are disposed as the amorphous magnetic alloy thin slice of high permeability, high resistivity, significantly improve the magnetic property of iron core 3 compared with traditional stalloy, and significantly reduce eddy current and the Joule heat that iron core 3 produces.The annular magnet 10 that high permeability, the amorphous magnetic alloy thin slice superposition of high resistivity are formed reduces the magnetic field degree of divergence in superconducting coil upper and lower end parts, also reduces the heat that superconducting coil produces due to A.C.power loss.

It should be noted that, in this article, the such as relational terms of " first " and " second " or the like is used merely to separate an entity or operation with another entity or operating space, and not necessarily requires or imply relation or the order that there is any this reality between these entities or operation.And, term " includes ", " comprising " or its any other variant are intended to comprising of nonexcludability, so that include that the process of a series of key element, method, article or equipment not only include those key elements, but also include other key elements being not expressly set out, or also include the key element intrinsic for this process, method, article or equipment.In the case of there is no more restriction, statement " including ... " key element limited, it is not excluded that there is also other identical element in including the process of described key element, method, article or equipment.

The above is only detailed description of the invention of the present utility model, makes to skilled artisans appreciate that or realize this utility model.Multiple amendment to these embodiments will be apparent to one skilled in the art, and generic principles defined herein can realize in the case of without departing from spirit or scope of the present utility model in other embodiments.Therefore, this utility model is not intended to be limited to the embodiments shown herein, and is to fit to the widest scope consistent with principles disclosed herein and features of novelty.

Claims (10)

1. a superconductive controllable reactor, it is characterized in that, including: winding (1), secondary superconduction winding (2), iron core (3), sub-cooled container (8), cooling tube (4), feed tube (5), drain pipe (6) and without magnetic support means (7)；

Described iron core (3) includes iron core frame (31) and iron core column (32), and it is internal that described iron core column (32) is vertically installed in described iron core frame (31)；

Described secondary superconduction winding (2) includes the first superconduction winding (21) and the second superconduction winding (22), described sub-cooled container (8) wraps up described first superconduction winding (21) and the second superconduction winding (22), and described first superconduction winding (21) is positioned at the inner side of described second superconduction winding (22), a described winding (1) is positioned at the periphery of described sub-cooled container (8), described sub-cooled container (8) is socketed on described iron core column (32) periphery, described first superconduction winding (21), the axis of the second superconduction winding (22) and a winding (1) and the axis of described iron core column (32) are same straight line；

Described cooling tube (4) includes cooling tube and lower cooling tube, described feed tube (5) is connected with described lower cooling tube, described drain pipe (6) is connected with described upper cooling tube, and described feed tube (5) and drain pipe (6) each extend over out described sub-cooled container (8)；Described upper cooling tube is arranged at one end of described secondary superconduction winding (2) and is positioned at the opening of described sub-cooled container (8), described lower cooling tube is arranged at the other end of described secondary superconduction winding (2), offers multiple Cooling Holes on the described upper cooling tube and lower cooling tube of described secondary superconduction winding (2) side；

Being respectively provided with described secondary superconduction winding (2) in location and the locating slot (71) of cooling tube (4) on the supporting surface of described support means without magnetic (7), described support means without magnetic (7) is correspondingly arranged in the two ends of described secondary superconduction winding (2).

Superconductive controllable reactor the most according to claim 1, it is characterized in that, described upper cooling tube includes cooling tube (42) on cooling tube on first (41) and second, and described lower cooling tube includes first time cooling tube (43) and second time cooling tube (44)；Wherein,

On described first, on cooling tube (41) and second, cooling tube (42) is respectively arranged at described first superconduction winding (21) and the outside of the second superconduction winding (22) upper end, described first time cooling tube (43) and second time cooling tube (44) are respectively arranged at described first superconduction winding (21) and the outside of the second superconduction winding (22) lower end, and have multiple hole towards described secondary superconduction winding (2) side on described cooling tube (4).

Superconductive controllable reactor the most according to claim 1, it is characterized in that, being additionally provided with circulation groove (72) in described support means without magnetic (7), described circulation groove (72) is arranged on the non-supported face of described support means without magnetic (7).

Superconductive controllable reactor the most according to claim 1, it is characterized in that, described sub-cooled container (8) is provided with composite Non-magnetic dewar, and described Dewar includes that watt body and FE Tiler, secondary superconduction winding (2) are arranged in described watt body；

Described FE Tiler includes basin body FE Tiler (81) and plane tile lid (82), described basin body FE Tiler (81) is mated with the opening of described sub-cooled container (8), and described flat board FE Tiler (82) is arranged on described basin body FE Tiler (81), is used for covering basin body FE Tiler (81)；

Described feed tube (5) and drain pipe (6) extend described sub-cooled container (8) by described basin body FE Tiler (81) and plane tile lid (82).

Superconductive controllable reactor the most according to claim 1, it is characterized in that, it is provided with the hole, location (311) mated with described feed tube (5) and drain pipe (6), described feed tube (5) and drain pipe (6) on described iron core frame (31) and extends described iron core (3) by hole, described location (311)；

Hole, described location (311) is located on the same line along the length direction setting of described iron core frame (31) and the center of circle in hole, described location (311)；

Described iron core frame (31) is set to the amorphous magnetic alloy thin slice of high permeability, high resistivity.

Superconductive controllable reactor the most according to claim 4, it is characterized in that, being provided with annular magnet (10) in the space formed between described basin body FE Tiler (81) and described flat board FE Tiler (82), described annular magnet (10) is set to the amorphous magnetic alloy thin slice of multiple mutually insulated and is formed by stacking.

Superconductive controllable reactor the most according to claim 1, it is characterised in that be provided with screen (9) circlewise between described winding (1) inner ring surface and described sub-cooled container (8) outer ring surface.

Superconductive controllable reactor the most according to claim 1, it is characterised in that described secondary superconduction winding (2) is set to multiple disk-type winding cascaded structure.

Superconductive controllable reactor the most according to claim 1, it is characterised in that described iron core frame (31) and iron core column (32) are formed by stacking by the amorphous magnetic alloy thin slice of multiple mutually insulateds.

Superconductive controllable reactor the most according to claim 1, it is characterized in that, described sub-cooled container (8), cooling tube (4), feed tube (5), drain pipe (6) and be set to without magnetic, insulation, low temperature resistant composite structure without magnetic support means (7).