DE2804397A1 - MAGNETIC FRAME FOR A TRANSFORMER OR A REACTOR - Google Patents

Description

MANNHEIM BROWhTBOVERI

280A397

Mp, no. 507/78 Mannheim, January 30, 1978

ZFE / P 1, Gö / Hz

Magnetic frame for a transformer or a choke coil

The invention relates to a magnet frame for a single or multi-phase high-voltage reactor transformer or a Choke coil for very high short-circuit voltages or very large leakage flux, with at least one core column and the associated core back yokes, as well as coaxially arranged windings around the core column.

A reactor transformer is part of a static system for the compensation of reactive power in electrical Energy transmission systems. The reactive power compensation is used to stabilize the voltage or to maintain certain Voltage limits, to reduce transmission losses, and it enables transmission lines to be exploited to a high degree.

Static compensation systems consisting of a reactor transformer, which can serve as a reactive power source, a control device, a measuring device and a capacitor bank or a filter device are known.

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January 30, 1978 507/78

For the reactor transformer whose primary winding is connected to the
network to be stabilized and on its secondary winding the! Control device is connected, there are only two operating states; The state of the open (no-load) secondary winding and the state in which the secondary winding is! is closed (short-circuited). Reactor transformers,
which are suitable for use in compensation systems for high
and high voltage networks are provided which are constructed advanta- J adhesive such that j concentrically around the core column which leads the magnetic flux in the idle, the secondary \ winding is arranged. The primary winding, which consists of two groups wound in opposite directions, and its high-voltage input are arranged concentrically above this
lies on the outer circumference in the axial center of the winding. Since j the ends of the high-voltage winding are mostly in operation; are grounded, there is only a small isolation distance for them
required against the yokes. '

With this winding arrangement, the two result

the aforementioned possible operating cases different j

Course of the magnetic force flux. When running empty-!

the secondary winding has the flux in the iron core and j

closes with single-phase versions via its j

Return yokes. The flux runs exclusively in the closed iron circle and is with the primary winding and
fully interlinked with the secondary winding.

In the event of a short circuit in the internal secondary winding remains
the flux linkage of the constant voltage
Primary winding unchanged, while the flux linkage j of the short-circuited winding must be zero. This ■ means that the full magnetic flux from the core

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column is displaced into the space inside and between the windings and close outside the primary winding got to. The return flow can only partially take place via the return yokes; lifts in three-phase arrangements part of the piiasen-shifted rivers in the yokes each other up. A significant part of the power flow will close over the boiler walls and on the way enforce inactive metallic construction parts there. Magnetic fluxes that carry metallic conductive components through set, cause eddy currents in these, which lead to additional losses and harmful warming.

The invention is based on the object of providing a magnetic frame of the type described at the beginning with simple means to create in which the aforementioned adverse effects do not occur in the event of a short-circuited secondary winding, by ensuring that the flow is kept away from all inactive components and from the boiler wall will.

According to the invention this is achieved in that the core yoke are provided with auxiliary yokes, the magnetically low-resistance return paths for the two axial ends of the windings to form exiting flux.

In advantageous embodiments of the subject matter of the invention it can be provided that the auxiliary yokes act as shielding yokes are formed, which mechanically with the core return yokes are connected that the shielding yokes parallel to the stratification of the core column or parallel to the stratification the core return yokes layered transformer sheets exist that the core yoke yokes and the shield yokes

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28Q4397

are held together pressed together by means of end plates, and that the plan area of the upper and lower shielding yokes includes the outer diameter of the outer winding and includes the total leakage flux.

This measure ensures that exiting at the upper and lower axial winding ends magnetic flux magnetically low-resistance return paths are created on which practically no eddy current losses or magnetic reversal losses can occur.

The following is a conventional magnet frame and an exemplary embodiment of the subject matter of the invention with the aid of the enclosed Drawing described in more detail. Show it:

Fig. 1 is a schematic half representation of a transformer with a conventional magnet frame with the at no-load secondary winding adjusting magnetic flux curve;

FIG. 2 shows the transformer from FIG. 1 with that which occurs when the secondary winding is short-circuited Force flow curve;

3 shows a transformer with a magnet frame according to the invention with the secondary winding when the secondary winding is idle established magnetic flux curve;

4 shows a transformer with a magnet frame according to the invention with that with the secondary winding short-circuited developing force flow curve;

5 shows a transformer with a magnet frame according to the invention in a schematic overall view;

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_ £ _ 28ÖA397

Fig. 6 is a view in the direction of arrow A in Fig. 5; Fig. 7 is a view in the direction of arrow B in Fig. 6;

8 shows a section along the line I - I in FIG. 5 in an enlarged view;

9 shows a section along the line II-II in FIG. 5 in an enlarged view.

In Fig. 1 can be seen the course of the magnetic flux with the primary winding W 1 and fed in no-load secondary winding ¥ 2 in a transformer with conventional single-phase magnet frame. ., This flow runs through the core column 1 according to the arrow FL and closes over the return yokes 2 and 3. At three-phase magnetic racks, the flow closes over the pillars of the two remaining phases. The river runs thus exclusively in the closed iron circuit and is full of the primary winding and the secondary winding chained.

In the conventional single-phase magnet frame shown in FIG. 2, it can be seen that the short circuit of the internal secondary winding W 2, the flux linkage of the primary winding W which is at constant voltage remains unchanged, while the flux linkage of the short-circuited winding W 2 must be zero. That means that the full magnetic flux according to the arrows from the core column 4 into the space within and between the windings W 1, W 2 is displaced and must close outside the primary winding W 1. The inference of the river can only partially take place here via the return tabs 5, 6; in three-phase arrangements a part is lifted

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of the out-of-phase rivers in the yokes on each other. A significant part of the power flow will be but close "K" via the boiler walls and you can access the The way to get there, put through inactive metallic construction parts.

In the single-phase magnet frame according to the invention shown schematically in FIGS. 3 to 8, the magnet core or the return yokes 12, 14, 16, 18 mechanically connected to the core column 10 are designed with shielding yokes 20, 22, 24, 26. These shielding yokes consist of transformer sheets which are arranged or layered parallel to the transformer sheets forming the core column 10 and the return yokes 12, 14, 16, 18 (cf. FIGS. 8 and 9). In this way, the shielding yokes, the return yokes and the core column can be combined to form a single mechanical assembly which is held together by means of yoke end plates 28, 30 and press screws 34 and 36. The entire magnet frame is also held together by core bridges 38 and core supports 40, which serve as cross members, as well as longitudinal members 42, 44 and tie rods 46. 50 and 32. are non-conductive bandages for tensioning the yoke end plates 28, 30.

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Claims (5)

BROWN, BOVERI & CiE. AKTIENGESELLSCHAFT Ek MANNHEIM BROWN BOVERI Mp.no. 507/78 Mannheim, January 30, 1978 ZFE / P 1, Gö / Hz Patent claims: M.) Magnetic frame for a single or multi-phase high-voltage reactor transformer or a choke coil for very high short-circuit voltages or very large leakage flux, with at least one core column and the associated core back yoke, as well as arranged coaxially around the core column Windings, characterized in that the core yoke yokes (12, 14, 16, 18) are provided with auxiliary yokes (20, 22, 24, 26), the magnetic low-resistance return paths for the the two axial ends of the windings (11, 13) form exiting flux. 2. Magnet frame according to claim 1, characterized in that the auxiliary yokes (20, 22, 24, 26) as shielding yokes are formed, which with the core return yokes (12, 14, 16, 18) are mechanically connected. 3. Magnet frame according to claim 1 and 2, characterized in that the shielding yokes (20, 22, 24, 26) from parallel to Layering of the core column (10) or layered parallel to the layering of the core back yokes (12, 14, 16, 18) Transformer sheets exist. 909832/0075 ... / .... ORfGfNAL INSPECTED January 30, 1978 507/78 4. Magnet frame according to at least one of claims 3 rice, characterized in that the core return yokes and the shielding yokes are held together pressed together by means of end plates (28, 30). 5. Magnetic frame according to claim 2, characterized in that the plan area of the upper and lower shielding 3oche (20, 22) includes the outer diameter of the outer winding (11) and covers the entire leakage flux. 909832/0075