JP2006245363A - Transformer for mold-type instrument, and method for manufacturing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transformer for a full mold type instrument which can not only secure strict safety and reliability, but also realize further reduction of a total cost including easy manufacturing of the transformer itself for the mold-type instrument or easy mounting work of the transformer or easy/lightened maintenance and inspection works with less errors during the manufacture, and to provide a method for manufacturing the transformer for the mold-type instrument. <P>SOLUTION: The method for manufacturing a transformer for a mold-type instrument includes a winding-mounting step of positioning and concentrically arranging a primary winding 21 and a secondary winding 22 with the use of their lead lines as references, in such a manner that the ground-side lead line 24 of the primary winding 21 and the secondary-side lead lines 25, 26 of the secondary winding 22 are positioned on the same side so as to face the center axis of a concentric circle. The transformer for the mold-type instrument is manufactured, based on the method. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a method for manufacturing a molded instrument transformer suitable for a rooftop device of a train, and a molded instrument transformer formed by such a manufacturing method.

  Instrument transformers (also called VT) are widely used in power facilities. An instrument transformer may be used in a harsh environment, and examples thereof include an instrument transformer mounted as a roof equipment for an AC / DC train.

A method of using an instrument transformer mounted as a roof equipment of such an AC / DC train will be described with reference to the drawings. FIG. 9 is a circuit diagram of an example of an AC / DC train, and relates to the AC / DC detection circuit 500.
A current collector (pantograph) 501 is connected to the circuit breaker 502 and also connected to the primary winding of the instrument transformer 503 to detect whether the electrical system of the overhead wire is alternating current or direct current. The A first DC voltage relay resistor 505 and a second DC voltage relay resistor 506 are connected in series to the ground side of the instrument transformer 503 and grounded. An AC voltage relay 504 is connected to the secondary side of the instrument transformer 503, and a DC voltage relay 507 is connected in parallel to the second DC voltage relay resistor 506.

  In the AC section, an overhead wire voltage that is stepped down at the turn ratio of the instrument transformer 503 is generated on the secondary side of the instrument transformer 503, and the AC voltage relay 504 is operated so that the voltage of the overhead wire is AC. Detect that. At this time, the voltage divided by the voltage transformer 503, the first DC voltage relay resistor 505, and the second DC voltage relay resistor 506 is applied to the DC voltage relay 507, but the second DC voltage relay resistance The impedance of the primary winding of the instrument transformer 503 is much larger than the resistance value of the voltage transformer 506, and almost no voltage is generated in the second DC voltage relay resistor 506.

In the DC section, since the impedance of the primary winding of the instrument transformer 503 is only the resistance of the winding and becomes a negligible value, the DC voltage relay 507 includes the first DC voltage relay resistor 505. And the voltage divided by the second DC voltage relay resistor 506 is applied, and the DC voltage relay 507 is operated to detect that the voltage of the overhead wire is DC.
When AC / DC is detected in this way, the AC / DC switch 508 switches the path, and when a DC voltage is supplied, power is supplied to the induction motor 514 via the DC circuit 509, the filter capacitor 512, and the inverter device 513. When an AC voltage is supplied, power is supplied to the induction motor 514 via the transformer 510, the AC circuit 511, the filter capacitor 512, and the inverter device 513. Thus, the transformer for an instrument is employ | adopted for the AC / DC detection use etc. at the time of an overhead wire electric system switching.

  The above-mentioned instrument transformer can be used regardless of the type of insulation such as oil-filled type, but it is particularly required to be environmentally resistant as roof equipment for AC / DC trains. It is preferable to use a molded instrument transformer using an outdoor epoxy resin having good electrical and mechanical properties as an insulating material. Such polymer insulation materials such as outdoor epoxy resins have been developed mainly in European and American countries, and their performance is improving year by year.

  In light of this situation, the present applicant has also developed a molded-type instrument transformer as described in Patent Document 1 (Japanese Patent Laid-Open No. 2001-230136, title of the invention “instrument transformer”). Yes. FIG. 10 is a sectional view of a conventional instrument transformer. In this instrument transformer, as shown in FIG. 10, the interphase distance is shortened to enable the miniaturization of a closed type power receiving / distribution facility such as a distribution board, and a cylindrical primary winding integrally formed of insulating resin. The wire 601 and the secondary winding 602 are provided concentrically with a central hole, and the two sets of cut cores 603 and 604 are arranged in a shape of approximately 8 in cross section around the central hole. An instrument transformer 600 in which an insulating body 609 is formed by molding is sandwiched between windings 602 and the outer side is fastened and fixed with bands 605 to 608.

  In addition, the applicant has made further improvements, and as described in Non-Patent Document 1, an all-mold type instrumental transformation using an outdoor epoxy resin applied to an instrumental transformer that is one of the on-roof equipment for AC / DC trains. Has been developed and field tests have been conducted with good results.

JP 2001-230136 A Satoshi Amagasaki, Akira Yamagishi, Isao Saeki, Kazutaka Ukita, Naoyuki Oinuma, Yoshifumi Hododa, “Development of Outdoor Molded Instrument Transformer for Railway Vehicles”, The Institute of Electrical Engineers of Japan, “Electrical Society of Japan 2004” Proceedings of the Power and Energy Division Conference (5th volume) pp185, 186 "

However, in-vehicle instrument transformers are directly exposed to harsh environments such as weather conditions from Hokkaido to Kyushu nationwide, and severe safety and reliability are required due to normal conditions such as vibration and impact. Yes.
The instrument transformer according to Patent Document 1 shown in FIG. 10 is also one in which the outer sides of the two sets of cut cores 603 and 604 are fastened and fixed by bands 605, 606, 607, and 608, and is subjected to vibration and impact. For trains, it was necessary to increase the mechanical strength.
In addition, since the all-mould-type instrument transformer according to Non-Patent Document 1 is molded with resin, it cannot be changed after being molded, and there is a demand for ensuring that it is manufactured without error. It was.

  Therefore, the present invention has been made to solve the above-mentioned problems, and its purpose is not only to ensure strict safety and reliability, but also to manufacture molded instrument transformers and mold molds. All mold types that reduce errors during manufacturing, so that the total cost can be further reduced, including the ease of handling the installation work of instrument transformers and the ease and reduction of maintenance and inspection work. The present invention provides a method for manufacturing a molded instrument transformer and a molded instrument transformer based on the method.

The method for manufacturing a molded instrument transformer according to claim 1 of the present invention is as follows.
A primary winding wound in an odd-numbered layer in a multi-layered cylindrical shape, and a ground side lead wire and a high voltage side lead wire of the winding are drawn from the inner circumference on one side and from the outer circumference on the other side,
Secondary windings wound in an even number of layers in a multi-layer cylindrical shape, and the secondary lead wires of the windings are respectively drawn from the inner and outer circumferences on the same side;
A method of manufacturing a molded-type instrument transformer using
The primary winding and the secondary winding are arranged so that the ground-side lead wire of the primary winding and the secondary-side lead wire of the secondary winding are located on the same side and substantially opposite to the concentric center axis. A winding mounting step of concentrically arranging the wires while positioning the wires with reference to the respective leader lines;
An iron core mounting step in which the iron core is arranged in the center of the primary winding and the secondary winding to form a closed magnetic circuit;
Terminals are provided on the ground side lead wire and high voltage side lead wire of the primary winding and the secondary side lead wire of the secondary winding and placed in the mold. In-mold installation process for fixing in the mold,
Fill the mold with insulating resin and harden, primary winding, secondary winding, iron core, primary winding grounding lead wire and high voltage lead wire, secondary winding secondary lead wire, and , A molding process for embedding terminals and molding a solid insulator,
It is characterized by having.

Further, a method for manufacturing a molded instrument transformer according to claim 2 of the present invention includes:
A ground-side primary winding that is wound in an odd-numbered layer in a multi-layer cylindrical shape, and a connection-side lead wire is drawn from the inner periphery on one side of the winding, and a ground-side lead wire is drawn from the outer periphery on the other side; ,
A high-voltage side primary winding that is wound in an odd-numbered layer in a multi-layer cylindrical shape, and a connection-side lead wire is drawn from the inner circumference on one side of the winding, and a high-voltage side lead wire is drawn from the outer circumference on the other side; ,
Secondary windings wound in an even number of layers in a multi-layer cylindrical shape, and the secondary lead wires of the windings are respectively drawn from the inner and outer circumferences on the same side;
A method of manufacturing a molded-type instrument transformer using
A primary winding assembly process in which the primary winding is assembled by connecting the connection side lead wire between the ground side primary winding and the high voltage side primary winding;
The primary winding and the secondary winding are arranged so that the ground-side lead wire of the primary winding and the secondary-side lead wire of the secondary winding are located on the same side and substantially opposite to the concentric center axis. A winding mounting step of concentrically arranging the wires while positioning the wires with reference to the respective leader lines;
An iron core mounting step in which the iron core is arranged in the center of the primary winding and the secondary winding to form a closed magnetic circuit;
Terminals are provided on the ground side lead wire and high voltage side lead wire of the primary winding and the secondary side lead wire of the secondary winding and placed in the mold. In-mold installation process for fixing in the mold,
Fill the mold with insulating resin and harden, primary winding, secondary winding, iron core, primary winding grounding lead wire and high voltage lead wire, secondary winding secondary lead wire, and , A molding process for embedding terminals and molding a solid insulator,
It is characterized by having.

Further, a method for manufacturing a molded instrument transformer according to claim 3 of the present invention includes:
In the manufacturing method of the molded-type instrument transformer of Claim 1 or Claim 2,
In the winding mounting step, the ground-side lead wire of the primary winding and the secondary lead-out wire of the secondary winding are arranged on the same side and have substantially the same height at the counter electrode position in the center of the concentric circle, and high voltage The side lead line is arranged at the top of the center of the concentric circle.

Further, a method for manufacturing a molded instrument transformer according to claim 4 of the present invention includes:
In the manufacturing method of the transformer for mold type instruments according to any one of claims 1 to 3,
The in-mold installation step is characterized in that an insulating laminate is interposed between the ground side lead wire and the secondary side lead wire.

In addition, a method for manufacturing a molded instrument transformer according to claim 5 of the present invention is as follows.
A primary winding wound in an odd-numbered layer in a multi-layered cylindrical shape, and a ground side lead wire and a high voltage side lead wire of the winding are drawn from the inner circumference on one side and from the outer circumference on the other side,
Secondary windings wound in an even number of layers in a multi-layer cylindrical shape, and the secondary lead wires of the windings are respectively drawn from the inner and outer circumferences on the same side;
A tertiary winding wound in an even number layer in a multi-layer cylindrical shape, and the tertiary lead wire of the winding is drawn from the inner and outer circumferences on the same side,
A method of manufacturing a molded-type instrument transformer using
The grounding lead wire of the primary winding, the secondary lead wire of the secondary winding, and the tertiary lead wire of the tertiary winding are located on the same side and substantially opposite to the central axis of the concentric circle A winding mounting step of concentrically arranging the primary winding, the secondary winding and the tertiary winding while positioning them with reference to the respective lead lines;
An iron core mounting process in which the iron core is arranged at the center of the primary winding, secondary winding and tertiary winding to form a closed magnetic circuit;
Terminals are provided on the ground side lead wire and high voltage side lead wire of the primary winding, the secondary lead wire of the secondary winding, and the tertiary lead wire of the tertiary winding and placed in the mold, and the iron core An in-mold installation process for fixing the winding in the mold via a monopod;
Fill the mold with insulating resin and harden it. Primary winding, secondary winding, tertiary winding, iron core, primary winding grounding lead wire and high voltage lead wire, secondary winding secondary side A lead wire, a tertiary lead wire of the tertiary winding, and a molding step of embedding a terminal to form a solid insulator;
It is characterized by having.

Further, a method for manufacturing a molded instrument transformer according to claim 6 of the present invention includes:
A ground-side primary winding that is wound in an odd-numbered layer in a multi-layer cylindrical shape, and a connection-side lead wire is drawn from the inner periphery on one side of the winding, and a ground-side lead wire is drawn from the outer periphery on the other side; ,
A high-voltage side primary winding that is wound in an odd-numbered layer in a multi-layer cylindrical shape, and a connection-side lead wire is drawn from the inner circumference on one side of the winding, and a high-voltage side lead wire is drawn from the outer circumference on the other side; ,
Secondary windings wound in an even number of layers in a multi-layer cylindrical shape, and the secondary lead wires of the windings are respectively drawn from the inner and outer circumferences on the same side;
A tertiary winding wound in an even number layer in a multi-layer cylindrical shape, and the tertiary lead wire of the winding is drawn from the inner and outer circumferences on the same side,
A method of manufacturing a molded-type instrument transformer using
A primary winding assembly process in which the primary winding is assembled by connecting the connection side lead wire between the ground side primary winding and the high voltage side primary winding;
The grounding lead wire of the primary winding, the secondary lead wire of the secondary winding, and the tertiary lead wire of the tertiary winding are located on the same side and substantially opposite to the central axis of the concentric circle A winding mounting step of concentrically arranging the primary winding, the secondary winding and the tertiary winding while positioning them with reference to the respective lead lines;
An iron core mounting process in which the iron core is arranged at the center of the primary winding, secondary winding and tertiary winding to form a closed magnetic circuit;
Terminals are provided on the ground side lead wire and high voltage side lead wire of the primary winding, the secondary lead wire of the secondary winding, and the tertiary lead wire of the tertiary winding and placed in the mold, and the iron core An in-mold installation process for fixing the winding in the mold via a monopod;
Fill the mold with insulating resin and harden it. Primary winding, secondary winding, tertiary winding, iron core, primary winding grounding lead wire and high voltage lead wire, secondary winding secondary side A lead wire, a tertiary lead wire of the tertiary winding, and a molding step of embedding a terminal to form a solid insulator;
It is characterized by having.

A method for manufacturing a molded instrument transformer according to claim 7 of the present invention is as follows.
In the manufacturing method of the transformer for molded instruments according to claim 5 or 6,
In the winding mounting step, the grounding-side lead wire of the primary winding, the secondary-side lead wire of the secondary winding, and the tertiary-side lead wire of the tertiary winding are arranged on the same side and the counter electrode at the center of the concentric circle The positions are approximately the same height, and the high-voltage side lead line is arranged at the top of the center of the concentric circle.

A method for manufacturing a molded instrument transformer according to claim 8 of the present invention includes:
In the manufacturing method of the molded-type instrument transformer as described in any one of Claims 5-7,
The molding step is characterized in that an insulating laminate is interposed between the ground-side lead wire, the secondary-side lead wire, or the tertiary-side lead wire.

A method for manufacturing a molded instrument transformer according to claim 9 of the present invention is as follows.
In the manufacturing method of the transformer for mold type instruments according to any one of claims 1 to 8,
In the in-mold installation step, a solid insulator having an epoxy resin as a main ingredient is molded as an insulating resin.

A method for manufacturing a molded instrument transformer according to claim 10 of the present invention includes:
In the manufacturing method of the transformer for molded instruments according to claim 9,
The insulating resin is
A cycloaliphatic epoxy resin as the main agent,
Phthalic anhydride as a curing agent,
An organometallic complex as a curing accelerator;
Fused quartz as filler,
It is characterized by using as a solid insulator for outdoor use.

A method for manufacturing a molded instrument transformer according to claim 11 of the present invention is as follows.
In the manufacturing method of the transformer for mold type instruments according to any one of claims 1 to 10,
In the molding step,
Having a first coating agent application step of applying a water repellent coating agent on the release agent layer applied to the inner surface of the mold before filling with the insulating resin;
The water-repellent coating agent is cured together with the insulating resin.

A method for manufacturing a molded instrument transformer according to claim 12 of the present invention includes:
In the manufacturing method of the transformer for mold type instruments according to any one of claims 1 to 11,
In the molding step,
Having a second coating agent coating step of covering the surface of the insulating resin which has been released from the mold and cured after filling with the insulating resin with a water repellent coating agent,
The water-repellent coating agent is cured together with the insulating resin.

A method for manufacturing a molded instrument transformer according to claim 13 of the present invention is as follows.
In the manufacturing method of the molded-type instrument transformer of Claim 11 or Claim 12,
In the first coating agent application step and / or the second coating agent application step, a silicone-based or fluorine-based water-repellent coating agent is cured to form a water-repellent coating layer.

The molded instrument transformer according to claim 14 of the present invention is:
The solid insulator for a molded instrument transformer manufactured based on the method for manufacturing a molded instrument transformer according to any one of claims 1 to 13,
An insulating body that covers the winding and the iron core with an insulating resin;
A high-pressure side bushing that covers the high-voltage side lead wire and the high-voltage side terminal with an insulating resin, is provided in a substantially cylindrical shape along the high-voltage side lead wire, and has a concavo-convex crease in the central axial section;
A low-pressure side bushing that covers the ground-side lead wire and the ground-side terminal with an insulating resin, is provided in a substantially cylindrical shape along the ground-side lead wire, and has a concavo-convex fold portion in the cross section in the central axis direction;
The secondary lead wire and secondary terminal extending in a direction substantially parallel to the central axis are coated with insulating resin, or the secondary lead wire, tertiary lead wire, and secondary extending in a direction substantially parallel to the central axis. A terminal block covering the side terminal and the tertiary side terminal with an insulating resin and projecting in a substantially truncated cone shape;
Is formed.

  According to the present invention, not only to ensure strict safety and reliability, but also ease of handling of the fabrication of the molded instrument transformer itself and the mounting work of the molded instrument transformer, or maintenance and inspection work Manufacturing method of a molded-type transformer for all types of molds so that errors in manufacturing are reduced so that the total cost can be further reduced, including the ease and mitigation of molds, and molded-type meters based on the method The transformer itself can be provided.

  The best mode for carrying out the present invention will be described with reference to the drawings. FIG. 1 is a perspective external view of a molded-type instrument transformer according to this embodiment. The mold-type instrument transformer 100 is specifically a grounded-type instrument transformer (EVT). Hereinafter, unless otherwise specified, the molded-type instrument transformer 100 is a single phase. As shown in FIG. 1, the molded instrument transformer 100 includes a pedestal 1, an insulating body 2, a high voltage side bushing 3, a primary U terminal 4, a low voltage side bushing 5, a primary V terminal 6, a terminal block 7, and a secondary u. A terminal 8 and a secondary v terminal 9 are provided.

  A transformer body is molded in the insulating body. FIG. 2 is an explanatory diagram of the transformer body, FIG. 2A is a structural diagram of the transformer, and FIG. 2B is a model diagram of the primary winding and the secondary winding. As shown in FIG. 2A, the transformer body 20 includes a primary winding 21, a secondary winding 22, a high voltage side lead wire 23, a ground side lead wire 24, secondary side lead wires 25 and 26, and an iron core 27. It has.

Subsequently, each configuration will be described. First, the transformer main body 20 will be described.
As shown in FIG. 2B, the primary winding 21 has a multi-layered cylindrical shape and is wound around an odd number of layers (five layers in FIG. The high-side lead wire 23 that is the end of the winding is drawn linearly from the inner circumference on one side and from the outer circumference on the other side.

  As shown in FIG. 2 (b), the secondary winding 22 is a multi-layered cylindrical shape, wound around an even number of layers (two layers in FIG. 2 (b)), and the secondary lead wire that is the winding start of the winding. 26 and the secondary lead wire 25 which is the end of winding are each drawn out linearly from the inner and outer circumferences on the same side.

  As shown in FIG. 2A, the primary winding 21 and the secondary winding 22 are arranged concentrically, and an iron core 27 is inserted through the central axis. The iron core 27 can employ various forms such as a cut core and a strip-assembled iron core. The transformer body 20 is formed in this way.

  The tip of the high voltage side lead wire 23 of the primary winding 21 is connected to a primary U terminal 4 (see FIG. 1) which is a high voltage side terminal connected to the bus. As shown in FIG. 2 (a), the high-voltage side lead wire 23 extends in a direction substantially parallel to the central axis, and the high-voltage side lead wire 23 and the primary U terminal 4 are shown in FIG. A high pressure side bushing 3 is provided which is covered with an insulating resin, is provided in a substantially cylindrical shape along the high voltage side lead wire 23, has a concavo-convex crease in the cross section in the central axis direction, and increases the creeping distance. The high voltage side is arranged on the upper side near the current collector, for example, in consideration of mounting on the roof of a train.

Further, it is connected to the primary V terminal 6 (see FIG. 1) which is a ground side terminal to be grounded to the tip of the ground side lead wire 24. As shown in FIG. 2A, the ground-side lead wire 24 extends in a direction substantially parallel to the central axis, and the ground-side lead wire 24 and the primary V terminal 6 are shown in FIG. A low-pressure side bushing 5 is provided which is covered with an insulating resin, is provided in a substantially cylindrical shape along the ground-side lead line 24, has a concave-convex fold portion in the cross section in the central axis direction, and increases the creeping distance. The low pressure side is disposed at a lower position than the high pressure side.
The high-voltage side bushing 3 and the low-voltage side bushing 5 improve and stabilize the insulation performance of the molded-type instrument transformer 100 together with the internal configuration and the external shape.

  The tip of the secondary lead wire 25 drawn from the outer periphery of the secondary winding 22 is connected to the secondary u terminal 8 (see FIG. 1), which is a secondary side terminal, and the secondary lead wire 26 The tip is connected to a secondary v terminal 9 (see FIG. 1) which is a secondary side terminal. These secondary u terminal 8 and secondary v terminal 9 are provided on the terminal block 7 and become terminals on the output voltage side transformed from the bus voltage.

  As shown in FIG. 1, the molded-type instrument transformer 100 has only the primary U terminal 4 that is a high-voltage side terminal arranged on one side, and is a primary V terminal 6 that is a ground side terminal, and a secondary side terminal. The secondary u terminal 8 and the secondary v terminal 9 are arranged on the other side, and the high voltage side terminal and the other terminal are separately located. Thus, consideration is given to making the secondary u terminal 8 and the secondary v terminal 9 which are secondary terminals less susceptible to the influence from the high-voltage bus voltage.

As shown in FIG. 1, the insulating body 2 includes the entire transformer body 20, a high-voltage side bushing 3, a primary U terminal 4, a low-voltage side bushing 5, a primary V terminal 6, a terminal block 7, and a secondary u terminal. 8 and a part of the secondary v terminal 9 are formed by being embedded with a molded insulating resin.
A pedestal 1 is attached to the lower side of the insulating main body 2 and is mounted on the roof of the train with a bolt that has passed through the hole of the pedestal 1 and is equipped.

The specifications of such a molded instrument transformer 100 are as shown in the following table.

Each lead wire may be provided with a laminated insulating plate in order to position the lead wire at the beginning and end of winding as a common wire and prevent mutual contact. Hereinafter, a description will be given with reference to FIG. FIG. 3 is an explanatory view of a laminated insulating plate, FIG. 3 (a) is an assembly view, and FIG. 3 (b) is an exploded view. As shown in FIG. 3A, the laminated insulating plate 30 includes a main body 30a and a hole 30b. As shown in FIG. 3B, the laminated insulating plate 30 is provided with a central portion 32 provided with groove portions 32a on both sides and two side end portions 31 provided with groove portions 31a. The side end portions 31 are formed on both sides of the central portion 32 so that 31a and 32a face each other. The secondary lead wires 25 and 26 are inserted into the holes 30b to ensure insulation.
In addition, a metal round bar such as copper, copper alloy, or aluminum may be interposed between the winding and the terminal to avoid contact.
The molded instrument transformer 100 is configured in this way.

  Next, a method for manufacturing such a molded instrument transformer 100 will be described. In addition, assembling molds, arranging and pre-processing each part (for example, processing for applying resin stress buffering to the iron core 27, insulation of the surface where the primary winding 21 and the secondary winding 22 are in contact with each other) It is assumed that the winding inter-layer insulation process for securing is performed in advance.

In step 1, the ground-side lead wire 24 of the primary winding 21 and the secondary lead-out wires 25 and 26 of the secondary winding 22 are located on the same side and substantially opposite to the central axis of the concentric circle. In this way, the primary winding 21 and the secondary winding 22 are arranged concentrically while being positioned with reference to the respective lead lines (winding mounting step). In particular, the primary winding 21 has an advantage that erroneous installation can be reduced because the leader drawn from the inner circumference can be distinguished from the ground-side leader 24.
In this case, as shown in FIG. 2A, the ground-side lead wire 24 of the primary winding 21 drawn from the inner periphery and the secondary-side lead wires 25 and 26 of the secondary winding 22 are connected to the same side. When the position of the ground-side lead wire 24 is 0 ° with respect to the central axis of the concentric circle, the secondary lead wires 25 and 26 are rotated about 180 ° with respect to the central axis. The high-voltage side lead wire 23 is rotated by about 90 ° with respect to the central axis of the concentric circle and is arranged at a substantially top position on the central axis. Because of this arrangement, mistakes (such as accidentally placing the high-voltage side lead wire and the secondary side lead wire on the same side) are unlikely to occur when the primary winding 21 and the secondary winding 22 are assembled. There is an advantage. The mold-type instrument transformer 100, which is an all-mold type, is molded with resin and cannot be changed after being molded. However, in this embodiment, consideration is given to ensure that it is manufactured without error. .

  Step 2 is a step of forming the closed magnetic circuit by placing the iron core 27 at the center of the primary winding 21 and the secondary winding 22 (iron mounting step). The iron core 27 is formed by assembling in accordance with various forms such as a cut core and a strip assembly iron core.

  Step 3 is a step of assembling the mold. In particular, the mold divided into a plurality of parts is assembled to the open state.

  In step 4, a mold release agent is applied to the inner surface of the mold that is in an open state so that the insulating resin can be easily peeled off.

Step 5 is a step of further applying a water-repellent coating agent on the release agent layer on the inner surface of the mold (first coating agent application step). This water-repellent coating agent is a silicone-based or fluorine-based water-repellent coating agent that is in a semi-dry state and has a little fluidity, and a multilayer coating is applied to the surface of the release agent applied to the inner surface of the mold. Apply as follows.
As this water-repellent coating agent, a water-repellent coating agent (for example, product name “HIREC450” manufactured by NTT Advanced Technology Co., Ltd.) having a physical property value close to the physical property value (for example, linear expansion coefficient) of an epoxy resin as an insulating resin is used. It is desirable to use it so that the shrinkage difference due to thermal behavior is reduced.

  Step 6 is to place and fix terminals and other inserts such as mounting bosses and internal wiring at predetermined positions in the mold, and then to mold the mold to a state where an insulating resin can be injected. This is a process of assembling the mold (in-mold installation process). Specifically, the primary V terminal 6 is connected to the ground-side lead wire 24 of the primary winding 21, the primary U terminal 4 is connected to the high-voltage-side lead wire 23 of the primary winding 21, and the secondary lead-out wire 25 of the secondary winding 22. The secondary u terminal 8 is connected to the secondary lead wire 26 of the secondary winding 22, and the secondary v terminal 9 is connected to the inner surface of the mold, and the transformer is connected via the monopod of the iron core 27. The main body 20 is fixed to the inner surface of the mold. In each winding, since the lead wire is smoothly routed from the beginning to the end of the winding to the respective terminals in parallel with the central axis at the shortest position, it is very easy to dispose them on the inner surface of the mold. In step 6, the laminated insulating plate 30 is also arranged at a predetermined position with the secondary lead wires 25 and 26 inserted through the hole portions 30b. By this step 6, the molds in the open state are assembled together so that the insulating resin can be filled.

  In step 7, the mold is filled with a fluid insulating resin and hardened, and the primary winding 21, the secondary winding 22, the iron core 27, the grounding lead wire 24 of the primary winding 21, and the high voltage lead wire are drawn. 23, the secondary lead wires 25 and 26 of the secondary winding 22, the primary U terminal 4, the primary V terminal 6, the secondary u terminal 8, the secondary v terminal 9, and the laminated insulating plate 30 are embedded. It is a process (molding process) for molding a solid insulator.

  As an example of the insulating resin, an outdoor resin containing a cycloaliphatic epoxy resin as a main agent, phthalic anhydride as a curing agent, an organometallic complex as a curing accelerator, and fused quartz as a filler. Insulating resin, more specifically, 100 parts by weight of glycidyl ester type epoxy resin (CY184 manufactured by Bantico) as a matrix resin and 80 parts by weight of hexahydrophthalic anhydride (Shikajid HH manufactured by Shin Nippon Rika Co., Ltd.) as a curing agent A molding resin composition in which 4 parts by weight of an organometallic complex (DY065J, manufactured by Bantico) is blended as an accelerator and 330 parts by weight of amorphous fused quartz (manufactured by Tatsumori) is used as a filler (filler) is used. Of course, it is not limited to this, various resin blending, curing temperature, curing time, etc. are set as appropriate, and depending on conditions such as casting equipment and curing equipment, it is not limited to epoxy resin, but indoors, outdoors, etc. An insulating resin suitable for various applications may be employed.

Step 8 is a step of applying heat to the mold into which the insulating resin has been injected, and curing the insulating resin so that the insulating resin has a mechanical strength that allows release.
In step 9, the mold is divided again and the cured insulating resin is released from the mold.

In step 10, the insulating resin surface of the released insulating resin is treated. After the mold release, the resin surface cured in a semi-cured state is appropriately repaired.
In step 11, the surface of the insulating resin is subjected to a multilayer coating process (second coating agent application process) with a water repellent coating agent. The step 11 may be performed in parallel with the step 10.

  In step 12, the insulating resin and the water repellent coating agent released from the mold are cured. The water-repellent coating agent is cured again in a state where the insulating resin surface is covered so as to cover the surface of the insulating resin, and a water-repellent coating layer integrated with the solid insulator is formed on the surface. In this step, specifically, the insulating resin is heated in a heating furnace for a predetermined time and then gradually cooled and cured. After curing, finish processing such as polishing the surface. As a result, an insulating resin portion in which the insulating main body 1, the high-pressure side bushing 3, the low-pressure side bushing 5, and the terminal block 7 are integrated as shown in FIG. 1 is formed.

  In step 13, a molded instrument transformer 100 is completed through assembly and finishing operations such as frame mounting.

As described above, the molded instrument transformer 100 is completed through steps 1 to 13.
In Step 10, if the water-repellent coating layer is released in a state where it completely covers the entire surface of the solid insulator, it can be omitted.
Similarly, the second coating agent coating process in step 11 can be omitted if the water-repellent coating layer is released in a state where it completely covers the entire surface of the solid insulator. Of course, when it is not necessary to form the water repellent coating layer on the surface, even if these are omitted, there is no problem in forming the solid insulator. What is necessary is just to select suitably according to the actual use condition of the transformer 100 for mold type instruments.

  Such a molded instrument transformer 100 is shipped after a completion test is performed thereafter. In particular, grounded instrument transformers (EVT) mounted on railroad vehicles can be replaced or replaced with conventional products (oil-filled EVT). It is designed to be mounted on the vehicle roof via a metal frame so that the material can be selected, including the appearance of the body and the prevention of electrical contact with the body material.

  Since the molded-type instrument transformer 100 is mounted on the roof of a railway vehicle in a state where the central axis of the substantially cylindrical bushing coincides with the traveling direction of the railway vehicle, various factors affecting the fatigue strength characteristics with respect to the solid insulator (tensile , Compression, bending, etc.) Not only can long-term reliability be ensured by repeated load reduction action, but also can reduce wind noise due to wind pressure during high-speed running and damage to connection terminals.

Subsequently, a modified embodiment of the present invention will be described. FIG. 4 is an explanatory diagram of another transformer body, FIG. 4A is a structural diagram of the transformer, and FIG. 4B is a model diagram of a primary winding and a secondary winding.
In this embodiment, the structure of the primary winding 21 in the transformer main body 20 having the form described above with reference to FIG. 2 is slightly changed, and other configurations and manufacturing methods are the same as those described above. In this embodiment, only different points will be described, and the same components will be denoted by the same reference numerals and redundant description will be omitted.

As shown in FIG. 4A, the primary winding 21 ′ includes a high voltage side primary winding 211 and a ground side primary winding 212.
The high-voltage-side primary winding 211 has a multilayer cylindrical shape and is wound around an odd-numbered layer (five layers in FIG. 4B), and the connection-side lead wire 213 from the inner periphery on one side of the winding, The high-voltage side lead wires 23 are respectively drawn from the outer periphery on the side.
The ground side primary winding 212 has a multilayer cylindrical shape and is wound around an odd number of layers (5 layers in FIG. 4 (b)) so that the connection side lead wire 214 from the inner periphery on one side of the winding and the other side On the side, the ground-side lead wires 24 are respectively drawn from the outer periphery.
As shown in FIG. 4B, the connection-side lead lines 213 and 214 are connected to constitute the primary winding 21 ′.
In this case, the manufacturing method of the molded-type instrument transformer 100 is performed by connecting the connecting lead wires 213 and 214 with the high-voltage-side primary winding 211 and the ground-side primary winding 212 before the step 1 described above. It can be manufactured by performing a primary winding assembling process for assembling the windings and performing processes 1 to 13 in the same manner. In this case, in step 1, as shown in FIG. 4A, the ground side lead wire 24 of the primary winding 21 ′ and the secondary side lead wires 25 and 26 of the secondary winding 22 are placed on the same side. In addition, when the position of the ground-side lead wire 24 is 0 ° with respect to the central axis of the concentric circle, the secondary lead wires 25 and 26 of the secondary winding 22 are rotated about 180 ° with respect to the central axis. In addition, the high-voltage-side lead wire 23 is rotated at about 90 ° with respect to the central axis of the concentric circle and arranged at a substantially top position on the central axis. In the primary winding 21 ′, no mistake occurs because the high-voltage side lead wire 23 and the ground-side lead wire 24 are on the outer peripheral side from the outer periphery on both sides. Further, even if the angle is adjusted by rotating the high voltage side primary winding 211 and the ground side primary winding 212, the connection side lead wires 213 and 214 can absorb the kinks.

  In the transformer body 20 ′ employing such a primary winding 21 ′, the high-voltage side lead wire 23 and the ground-side lead wire 24 both come out from the outer periphery, and the high-voltage side lead wire 23 and the ground-side lead wire 24 are mistaken. No fear. Furthermore, the secondary high-voltage side lead wire 23 on the primary side, the secondary u terminal 8 and the secondary v terminal 9 which are secondary side terminals are further away from the ground-side lead wire 24. Consideration is made so that the secondary u terminal 8 and the secondary v terminal 9 that are secondary terminals are less susceptible to the influence from the high-voltage side lead wire 23 and the ground side lead wire 24.

  Next, a molded instrument transformer 100 'according to another embodiment will be described with reference to the drawings. FIG. 5 is a perspective external view of another embodiment of a molded instrument transformer. The molded-type instrument transformer 100 'refers to a single phase unless otherwise specified. As shown in FIG. 5, the molded instrument transformer 100 ′ includes a base 1, an insulating body 2, a high-voltage side bushing 3, a primary U terminal 4, a low-voltage side bushing 5, a primary V terminal 6, a terminal block 7, and a secondary A u terminal 8, a secondary v terminal 9, a tertiary a terminal 10, and a tertiary b terminal 11 are provided. Among these, the tertiary a terminal 10 and the tertiary b terminal 11 are used for residual voltage detection particularly by three-phase open Δ connection.

  A transformer body is molded in the insulating body. FIG. 6 is an explanatory diagram of the transformer body, FIG. 6A is a structural diagram of the transformer, and FIG. 6B is a model diagram of the primary winding, the secondary winding, and the tertiary winding. As shown in FIG. 6A, the transformer main body 40 includes a primary winding 41, a secondary winding 42, a high voltage side lead wire 43, a ground side lead wire 44, secondary side lead wires 45 and 46, and a tertiary winding. Line 47 and tertiary lead lines 48 and 49 are provided.

Subsequently, each configuration will be described. First, the transformer main body 40 will be described.
As shown in FIG. 6B, the primary winding 41 has a multi-layered cylindrical shape wound around an odd number of layers (five layers in FIG. 6B) and a ground-side lead wire 44 that is the winding start of the winding. The high-voltage-side lead wire 43, which is the end of winding, is drawn out linearly from the inner circumference on one side and from the outer circumference on the other side.

  As shown in FIG. 6 (b), the secondary winding 42 is a multi-layered cylindrical shape and is wound around an even number of layers (two layers in FIG. 6 (b)), and the secondary lead line is the winding start of the winding. 46 is drawn out linearly from the inner circumference on one side and the secondary lead wire 45 which is the end of winding is drawn out from the outer circumference on the other side.

  As shown in FIG. 6 (b), the tertiary winding 47 has a multilayer cylindrical shape and is wound around an even number of layers (two layers in FIG. 6 (b)). A tertiary lead wire 48, which is the end of winding, is drawn out linearly from the inner circumference on one side and from the outer circumference on the other side.

  The primary winding 41, the secondary winding 42, and the tertiary winding 47 are arranged concentrically as shown in FIG. 6A, and an iron core (not shown; The same type as the iron core 27 shown in FIG. Various forms, such as a cut core and a strip assembly iron core, can be adopted as the iron core. The transformer body 40 is formed in this way.

  The tip of the high voltage side lead wire 43 of the primary winding 41 is connected to a primary U terminal 4 (see FIG. 5) which is a high voltage side terminal connected to the bus. As shown in FIG. 6A, the high-voltage side lead wire 43 extends in a direction substantially parallel to the central axis, and the high-voltage side lead wire 43 and the primary U terminal 4 are arranged as shown in FIG. A high pressure side bushing 3 is provided which is covered with an insulating resin, is provided in a substantially cylindrical shape along the high voltage side lead wire 43, has a concavo-convex crease in the cross section in the central axis direction, and increases the creeping distance.

Further, it is connected to the primary V terminal 6 (see FIG. 5) which is a ground side terminal to be grounded to the tip of the ground side lead wire 44. As shown in FIG. 6A, the ground-side lead wire 44 extends in a direction substantially parallel to the central axis, and the ground-side lead wire 44 and the primary V terminal 6 are shown in FIG. A low-pressure side bushing 5 is provided which is covered with an insulating resin, is provided in a substantially cylindrical shape along the ground-side lead wire 44, has a concavo-convex crease in the cross section in the central axis direction, and increases the creepage distance.
The high-voltage side bushing 3 and the low-voltage side bushing 5 improve and stabilize the insulation performance of the molded-type instrument transformer 100 ′ as well as the internal configuration and the external shape.

  The tip of the secondary lead wire 45 drawn from the outer periphery of the secondary winding 42 is connected to the secondary u terminal 8 (see FIG. 5), which is a secondary side terminal, and the secondary lead wire 46 The tip is connected to a secondary v terminal 9 (see FIG. 5) which is a secondary side terminal. Further, the tip of the tertiary lead wire 48 drawn from the outer periphery of the tertiary winding 47 is the tertiary a terminal 10 (see FIG. 5) which is a tertiary side terminal, and the tip of the tertiary lead wire 49 is the tertiary side. Each is connected to a tertiary b terminal 11 (see FIG. 5) which is a terminal. These secondary u terminal 8, secondary v terminal 9, tertiary a terminal 10 and tertiary b terminal 11 are provided on the terminal block 7 and serve as terminals on the output voltage side transformed from the bus voltage.

  As shown in FIG. 5, the molded-type instrument transformer 100 ′ has only the primary U terminal 4 that is a high-voltage side terminal arranged on one side, the primary V terminal 6 that is a ground side terminal, and the secondary side terminal. A secondary u terminal 8, a secondary v terminal 9, a tertiary a terminal 10 and a tertiary b terminal 11 are arranged on the other side, and the high voltage side terminal and the other terminals are separately located. As a result, the influence from the high-voltage bus voltage is made less likely to be received by the secondary u terminal 8, the secondary v terminal 9, the tertiary a terminal 10 and the tertiary b terminal 11 which are the secondary terminals. is doing.

As shown in FIG. 5, the insulating body 2 includes the entire transformer body 20 ′, the high-voltage side bushing 3, the primary U terminal 4, the low-voltage side bushing 5, the primary V terminal 6, the terminal block 7, and the secondary u. Part of the terminal 8, the secondary v terminal 9, the tertiary a terminal 10 and the tertiary b terminal 11 is formed by being embedded with a molded insulating resin.
A pedestal 1 is attached to the lower side of the insulating main body 2 and is mounted on the roof of the train with a bolt that has passed through the hole of the pedestal 1 and is equipped.

Each lead wire may be provided with a laminated insulating plate in order to position the lead wire at the beginning and end of winding as a common wire and prevent mutual contact. Hereinafter, a description will be given with reference to FIG. FIG. 7 is an explanatory view of a laminated insulating plate, FIG. 7 (a) is an assembly view, and FIG. 7 (b) is an exploded view. As shown in FIG. 7A, the laminated insulating plate 50 includes a main body 50a and a hole 50b. As shown in FIG. 7 (b), the laminated insulating plate 50 has a central portion 52 provided with two grooves, upper and lower, on both sides and a total of four grooves 52a on both sides, and two grooves 51a on one side. The two side end portions 51 are prepared, and the side end portions 51 are arranged on both sides of the central portion 52 so that the grooves 51a and 52a face each other. The secondary lead wires 45 and 46 and the tertiary lead wires 48 and 49 are inserted into the holes 50b to ensure insulation.
Further, a round bar made of metal such as copper, copper alloy, or aluminum may be interposed between the winding and the terminal.
The molded instrument transformer 100 'is configured in this manner.

  Next, a method for manufacturing such a molded instrument transformer 100 'will be described. In addition, assembling molds, arranging and pre-processing each component (for example, processing for applying a resin stress buffering process to the iron core, the surface where the primary winding 41 and the secondary winding 42 are in contact, Winding interlayer insulation processing is performed in order to ensure insulation of the surface where the winding 42 and the tertiary winding 47 contact each other).

In step 1, the ground side lead wire 44 of the primary winding 41, the secondary side lead wires 45 and 46 of the secondary winding 42, and the tertiary side lead wires 48 and 49 of the tertiary winding 47 are on the same side. The primary winding 41, the secondary winding 42, and the tertiary winding 47 are arranged concentrically while being positioned on the basis of the respective lead lines so that they are positioned substantially opposite to the central axis of the concentric circle. Wire attachment process). In particular, the primary winding 41 has an advantage that erroneous installation can be avoided because the lead wire drawn from the inner periphery can be identified as the ground lead wire 44.
In this case, as shown in FIG. 6A, the ground-side lead wire 44 of the primary winding 41, the secondary lead wires 45 and 46 of the secondary winding 42, and the tertiary lead-out wire 48 of the tertiary winding 47. , 49 are arranged on the same side, and when the position of the ground-side lead wire 44 is 0 ° with respect to the central axis of the concentric circle, the secondary lead wires 45, 46 and the tertiary lead wires 48, 49 are Approximately the top position on the central axis by rotating the high-voltage side lead wire 43 by about 90 ° with respect to the central axis of the concentric circle, with the same height at the opposite position on the opposite side rotated about 180 ° with respect to the central axis. To place. Because of this arrangement, the primary winding 41, the secondary winding 42, and the tertiary winding 47 are mistakenly assembled (all the high-voltage side lead wire, secondary side lead wire, and tertiary side lead wire are on the same side. For example) is less likely to occur. The mold-type instrument transformer 100 ′, which is an all-mold type, is molded with resin and cannot be changed after being molded. However, in this embodiment, consideration is given to ensure that it is manufactured without error. Yes.

  Step 2 is a step of forming a closed magnetic circuit by placing the iron core at the center of the primary winding 41, the secondary winding 42, and the tertiary winding 47 (iron mounting step). The iron core is formed by assembling in accordance with various forms such as a cut core and a strip assembly iron core.

  Step 3 is a step of assembling the mold. In particular, the mold divided into a plurality of parts is assembled to the open state.

  In step 4, a mold release agent is applied to the inner surface of the mold that is in an open state so that the insulating resin can be easily peeled off.

  Step 5 is a step of further applying a water-repellent coating agent on the release agent layer on the inner surface of the mold (first coating agent application step). The process 5 here is the same as the process 5 of the method for manufacturing the molded instrument transformer 100 described with reference to FIGS. 1 to 4, and a detailed description thereof is omitted.

  Step 6 is to place and fix terminals and other inserts such as mounting bosses and internal wiring at predetermined positions in the mold, and then to mold the mold to a state where an insulating resin can be injected. This is a process of assembling the mold (in-mold installation process). Specifically, the primary V terminal 6 is connected to the ground side lead wire 44 of the primary winding 41, the primary U terminal 4 is connected to the high voltage side lead wire 43 of the primary winding 41, and the secondary lead wire 45 of the secondary winding 42. The secondary u terminal 8, the secondary v terminal 9 on the secondary lead wire 46 of the secondary winding 42, the tertiary a terminal 10 on the tertiary lead wire 48 of the tertiary winding 47, and the tertiary winding 47 The tertiary b terminal 11 is connected to the tertiary lead wire 49 and disposed on the inner surface of the mold, and the transformer body 20 ′ is fixed to the inner surface of the mold via a monopod of the iron core. Since the lead wires are routed from the beginning and end of each winding to the respective terminals in the shortest position in parallel to the central axis, the arrangement work on the inner surfaces of these dies is extremely easy. In step 6, the laminated insulating plate 50 is also arranged at a predetermined position with the secondary lead wires 45 and 46 and the tertiary lead wires 48 and 49 inserted through the holes 50b.

In step 7, the mold is filled with a fluid insulating resin and cured, and the primary winding 41, the secondary winding 42, the iron core, the grounding lead wire 44 and the high voltage lead wire 43 of the primary winding 41 are processed. , Secondary lead wires 45 and 46 of the secondary winding 42, tertiary lead wires 48 and 49 of the tertiary winding 47, primary U terminal 4, primary V terminal 6, secondary u terminal 8, secondary v terminal 9 , The tertiary a terminal 10, the tertiary v terminal 11, and the laminated insulating plate 50 are embedded (molding process).
In this step 7 as well, it is preferable to use an insulating resin as described in step 7 of the method of manufacturing the molded instrument transformer 100 described with reference to FIGS. The overlapping description of this insulating resin is omitted.

Step 8 is a step of applying heat to the mold into which the insulating resin has been injected, and curing the insulating resin so that the insulating resin has a mechanical strength that allows release.
In step 9, the mold is divided again and the cured insulating resin is released from the mold.

In step 10, the insulating resin surface of the released insulating resin is treated. After the mold release, the resin surface cured in a semi-cured state is appropriately repaired.
In step 11, the surface of the insulating resin is subjected to a multilayer coating process (second coating agent application process) with a water repellent coating agent. The step 11 may be performed in parallel with the step 10.

  In step 12, the insulating resin and the water repellent coating agent released from the mold are cured. The water-repellent coating agent is cured again in a state where the insulating resin surface is covered so as to cover the surface of the insulating resin, and a water-repellent coating layer integrated with the solid insulator is formed on the surface. In this step 12, specifically, the insulating resin is heated in a heating furnace for a predetermined time and then gradually cooled and cured. After curing, finish processing such as polishing the surface. As a result, an insulating resin portion in which the insulating main body 1, the high-voltage side bushing 3, the low-voltage side bushing 5, and the terminal block 7 are integrated as shown in FIG. 5 is formed.

  In step 13, a molded instrument transformer 100 ′ is completed through assembly and finishing operations such as frame mounting.

As described above, the molded instrument transformer 100 ′ is completed through steps 1 to 13.
In Step 10, if the water-repellent coating layer is released in a state where it completely covers the entire surface of the solid insulator, it can be omitted.
Similarly, the second coating agent coating process in step 11 can be omitted if the water-repellent coating layer is released in a state where it completely covers the entire surface of the solid insulator. Of course, when it is not necessary to form the water repellent coating layer on the surface, even if these are omitted, there is no problem in forming the solid insulator. What is necessary is just to select suitably according to the actual use condition of the transformer 100 for mold type instruments.

  Such a molded instrument transformer 100 ′ is shipped after a completion test is performed thereafter. In particular, grounded instrument transformers (EVT) mounted on railroad vehicles can be replaced or replaced with conventional products (oil-filled EVT). It is designed to be mounted on the vehicle roof via a metal frame so that the material can be selected, including the appearance of the body and the prevention of electrical contact with the body material.

  Since the molded-type instrument transformer 100 ′ is mounted on the roof of a railway vehicle in a state where the central axis of the substantially cylindrical bushing coincides with the traveling direction of the railway vehicle, various factors affecting the fatigue strength characteristics with respect to solid insulation ( (Tension, compression, bending, etc.) Not only can long-term reliability be ensured by the action of reducing repeated loads, but also reduction of wind noise caused by wind pressure during high-speed running and damage to connection terminals.

Subsequently, a modified embodiment of the present invention will be described. FIG. 8 is an explanatory diagram of another transformer body, FIG. 8A is a structural diagram of the transformer, and FIG. 8B is a model diagram of a primary winding, a secondary winding, and a tertiary winding.
In this embodiment, the structure of the primary winding 41 of the transformer main body 40 having the form described above with reference to FIG. 6 is slightly changed, and other configurations and manufacturing methods are the same as those described above. In this embodiment, only different points will be described, and the same components will be denoted by the same reference numerals and redundant description will be omitted.

The primary winding 41 ′ includes a high voltage side primary winding 411 and a ground side primary winding 412.
The high-voltage side primary winding 411 is a multi-layer cylindrical shape wound around an odd-numbered layer, and on one side of the winding, the connection side lead line 413 is formed from the inner periphery, and on the other side, the high-voltage side lead line 43 is formed from the outer periphery. Each winding is drawn out.
The ground side primary winding 412 is a multi-layered cylindrical shape wound around an odd-numbered layer, and on one side of the winding, the connection side lead line 414 is formed from the inner periphery, and on the other side, the ground side lead line 44 is formed from the outer periphery. Each winding is drawn out.
As shown in FIG. 8B, the connection-side lead lines 413 and 414 are connected to form the primary winding 41 ′.
In this case, the manufacturing method of the molded-type instrument transformer 100 ′ is performed by connecting the connecting lead wires 413 and 414 with the ground-side primary winding 412 and the high-voltage side primary winding 411 before the step 1 described above. It can be manufactured by performing a primary winding assembly process for assembling the primary winding 41 ′ and then performing processes 1 to 13 in the same manner. In Step 1, as shown in FIG. 8A, the ground side lead wire 44 of the primary winding 41, the secondary lead wires 45 and 46 of the secondary winding 42, and the tertiary side lead of the tertiary winding 47 are provided. When the lines 48 and 49 are arranged on the same side and the position of the ground-side lead wire 44 is 0 ° with respect to the central axis of the concentric circle, the secondary lead wires 45 and 46 and the tertiary lead wire 48, 49 is rotated at about 180 ° with respect to the central axis, and at the opposite position on the opposite side, and the high-voltage side lead wire 43 is rotated about 90 ° with respect to the central axis of the concentric circle. It will be placed at the top position.

  In the transformer body 40 ′ employing such a primary winding 41 ′, the high-voltage side lead wire 43 and the ground-side lead wire 44 are both out of the outer periphery, and the high-voltage side lead wire 43 and the ground-side lead wire 44 are mistaken. No fear. Further, the influence from the high-voltage side lead wire 43 and the ground-side lead wire 44 of the primary side high voltage can thereby be influenced by the secondary u terminal 8, the secondary v terminal 9 that is the secondary side terminal, and the tertiary that is the tertiary side terminal. The a terminal 10 and the tertiary b terminal 11 are designed to be difficult to receive.

  The molded instrument transformers 100 and 100 'of the present invention have been described above. Molded instrument transformers 100 and 100 ′ thus manufactured, particularly suitable for mounting on railway vehicles, use solid insulators that are strong against vibration and impact, or have a water-repellent coating layer fixed to the solid insulators. As a result, the water repellency function of the surface is ensured for a long period of time, and the maintenance and inspection work can be facilitated or reduced even when directly exposed to a harsh environment.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective external view of a molded-type instrument transformer in the best mode for carrying out the present invention. It is explanatory drawing of a transformer main body, Fig.2 (a) is a structural diagram of a transformer, FIG.2 (b) is a model figure of a primary winding and a secondary winding. It is explanatory drawing of a laminated insulating board, FIG. 3 (a) is an assembly drawing, FIG.3 (b) is an exploded view. It is explanatory drawing of another transformer main body, Fig.4 (a) is a structural diagram of a transformer, FIG.4 (b) is a model figure of a primary winding and a secondary winding. It is a perspective external view of the mold-type instrument transformer of another form. FIG. 6 is an explanatory diagram of the transformer body, FIG. 6A is a structural diagram of the transformer, and FIG. 6B is a model diagram of the primary winding, the secondary winding, and the tertiary winding. It is explanatory drawing of a laminated insulating board, Fig.7 (a) is an assembly drawing, FIG.7 (b) is an exploded view. It is explanatory drawing of another transformer main body, Fig.8 (a) is a structural diagram of a transformer, FIG.8 (b) is a model figure of a primary winding, a secondary winding, and a tertiary winding. It is a circuit diagram of an example of an AC / DC train. It is a cross-sectional block diagram of the instrument transformer of a prior art.

Explanation of symbols

100, 100 ', 200, 200': Molded instrument transformer 1: Pedestal 2: Insulation body 3: High voltage side bushing 4: Primary U terminal 5: Low voltage side bushing 6: Primary V terminal 7: Terminal block 8: Two Next u terminal 9: Secondary v terminal 10: Tertiary a terminal 11: Tertiary b terminal 20, 20 ': Transformer main body 21, 21': Primary winding 211: High voltage side primary winding 212: Ground side primary winding 213 , 214: connection side lead wire 22: secondary winding 23: high voltage side lead wire 24: ground side lead wire 25, 26: secondary side lead wire 27: iron core 30: laminated insulating plate 30 a: main body 30 b: hole 31 : Side end portion 31a: Groove portion 32: Center portion 32a: Groove portions 40, 40 ': Transformer body 41, 41': Primary winding 411: High voltage side primary winding 412: Ground side primary windings 413, 414: Connection side Lead wire 42: secondary winding 43: high voltage side lead wire 44: ground side lead wire 5,46: secondary lead wire 47: a tertiary winding 48.49: tertiary side lead wire 50: laminated insulating plate 50a: body 50b: hole portion 51: side edge portion 51a: groove 52: central portion 52a: groove

Claims (14)

A primary winding wound in an odd-numbered layer in a multi-layered cylindrical shape, and a ground side lead wire and a high voltage side lead wire of the winding are drawn from the inner circumference on one side and from the outer circumference on the other side,
Secondary windings wound in an even number of layers in a multi-layer cylindrical shape, and the secondary lead wires of the windings are respectively drawn from the inner and outer circumferences on the same side;
A method of manufacturing a molded-type instrument transformer using
The primary winding and the secondary winding are arranged so that the ground-side lead wire of the primary winding and the secondary-side lead wire of the secondary winding are located on the same side and substantially opposite to the concentric center axis. A winding mounting step of concentrically arranging the wires while positioning the wires with reference to the respective leader lines;
An iron core mounting step in which the iron core is arranged in the center of the primary winding and the secondary winding to form a closed magnetic circuit;
Terminals are provided on the ground side lead wire and high voltage side lead wire of the primary winding and the secondary side lead wire of the secondary winding and placed in the mold. In-mold installation process for fixing in the mold,
Fill the mold with insulating resin and harden, primary winding, secondary winding, iron core, primary winding grounding lead wire and high voltage lead wire, secondary winding secondary lead wire, and , A molding process for embedding terminals and molding a solid insulator,
A method for manufacturing a molded-type instrument transformer, comprising: A ground-side primary winding that is wound in an odd-numbered layer in a multi-layer cylindrical shape, and a connection-side lead wire is drawn from the inner periphery on one side of the winding, and a ground-side lead wire is drawn from the outer periphery on the other side; ,
A high-voltage side primary winding that is wound in an odd-numbered layer in a multi-layer cylindrical shape, and a connection-side lead wire is drawn from the inner circumference on one side of the winding, and a high-voltage side lead wire is drawn from the outer circumference on the other side; ,
Secondary windings wound in an even number of layers in a multi-layer cylindrical shape, and the secondary lead wires of the windings are respectively drawn from the inner and outer circumferences on the same side;
A method of manufacturing a molded-type instrument transformer using
A primary winding assembly process in which the primary winding is assembled by connecting the connection side lead wire between the ground side primary winding and the high voltage side primary winding;
The primary winding and the secondary winding are arranged so that the ground-side lead wire of the primary winding and the secondary-side lead wire of the secondary winding are located on the same side and substantially opposite to the concentric center axis. A winding mounting step of concentrically arranging the wires while positioning the wires with reference to the respective leader lines;
An iron core mounting step in which the iron core is arranged in the center of the primary winding and the secondary winding to form a closed magnetic circuit;
Terminals are provided on the ground side lead wire and high voltage side lead wire of the primary winding and the secondary side lead wire of the secondary winding and placed in the mold. In-mold installation process for fixing in the mold,
Fill the mold with insulating resin and harden, primary winding, secondary winding, iron core, primary winding grounding lead wire and high voltage lead wire, secondary winding secondary lead wire, and , A molding process for embedding terminals and molding a solid insulator,
A method for manufacturing a molded-type instrument transformer, comprising: In the manufacturing method of the molded-type instrument transformer of Claim 1 or Claim 2,
In the winding mounting step, the ground-side lead wire of the primary winding and the secondary lead-out wire of the secondary winding are arranged on the same side and have substantially the same height at the counter electrode position in the center of the concentric circle, and high voltage A method for manufacturing a molded-type instrument transformer, characterized in that a side lead line is arranged at the top of the center of a concentric circle. In the manufacturing method of the transformer for mold type instruments according to any one of claims 1 to 3,
In the in-mold installation step, a method for manufacturing a molded-type instrument transformer, wherein an insulating laminate is interposed between a ground-side lead wire and a secondary-side lead wire. A primary winding wound in an odd-numbered layer in a multi-layered cylindrical shape, and a ground side lead wire and a high voltage side lead wire of the winding are drawn from the inner circumference on one side and from the outer circumference on the other side,
Secondary windings wound in an even number of layers in a multi-layer cylindrical shape, and the secondary lead wires of the windings are respectively drawn from the inner and outer circumferences on the same side;
A tertiary winding wound in an even number layer in a multi-layer cylindrical shape, and the tertiary lead wire of the winding is drawn from the inner and outer circumferences on the same side,
A method of manufacturing a molded-type instrument transformer using
The grounding lead wire of the primary winding, the secondary lead wire of the secondary winding, and the tertiary lead wire of the tertiary winding are located on the same side and substantially opposite to the central axis of the concentric circle A winding mounting step of concentrically arranging the primary winding, the secondary winding and the tertiary winding while positioning them with reference to the respective lead lines;
An iron core mounting process in which the iron core is arranged at the center of the primary winding, secondary winding and tertiary winding to form a closed magnetic circuit;
Terminals are provided on the ground side lead wire and high voltage side lead wire of the primary winding, the secondary lead wire of the secondary winding, and the tertiary lead wire of the tertiary winding and placed in the mold, and the iron core An in-mold installation process for fixing the winding in the mold via a monopod;
Fill the mold with insulating resin and harden it. Primary winding, secondary winding, tertiary winding, iron core, primary winding grounding lead wire and high voltage lead wire, secondary winding secondary side A lead wire, a tertiary lead wire of the tertiary winding, and a molding step of embedding a terminal to form a solid insulator;
A method for manufacturing a molded-type instrument transformer, comprising: A ground-side primary winding that is wound in an odd-numbered layer in a multi-layer cylindrical shape, and a connection-side lead wire is drawn from the inner periphery on one side of the winding, and a ground-side lead wire is drawn from the outer periphery on the other side; ,
A high-voltage side primary winding that is wound in an odd-numbered layer in a multi-layer cylindrical shape, and a connection-side lead wire is drawn from the inner circumference on one side of the winding, and a high-voltage side lead wire is drawn from the outer circumference on the other side; ,
Secondary windings wound in an even number of layers in a multi-layer cylindrical shape, and the secondary lead wires of the windings are respectively drawn from the inner and outer circumferences on the same side;
A tertiary winding wound in an even number layer in a multi-layer cylindrical shape, and the tertiary lead wire of the winding is drawn from the inner and outer circumferences on the same side,
A method of manufacturing a molded-type instrument transformer using
A primary winding assembly process in which the primary winding is assembled by connecting the connection side lead wire between the ground side primary winding and the high voltage side primary winding;
The grounding lead wire of the primary winding, the secondary lead wire of the secondary winding, and the tertiary lead wire of the tertiary winding are located on the same side and substantially opposite to the central axis of the concentric circle A winding mounting step of concentrically arranging the primary winding, the secondary winding and the tertiary winding while positioning them with reference to the respective lead lines;
An iron core mounting process in which the iron core is arranged at the center of the primary winding, secondary winding and tertiary winding to form a closed magnetic circuit;
Terminals are provided on the ground side lead wire and high voltage side lead wire of the primary winding, the secondary lead wire of the secondary winding, and the tertiary lead wire of the tertiary winding and placed in the mold, and the iron core An in-mold installation process for fixing the winding in the mold via a monopod;
Fill the mold with insulating resin and harden it. Primary winding, secondary winding, tertiary winding, iron core, primary winding grounding lead wire and high voltage lead wire, secondary winding secondary side A lead wire, a tertiary lead wire of the tertiary winding, and a molding step of embedding a terminal to form a solid insulator;
A method for manufacturing a molded-type instrument transformer, comprising: In the manufacturing method of the transformer for molded instruments according to claim 5 or 6,
In the winding mounting step, the grounding-side lead wire of the primary winding, the secondary-side lead wire of the secondary winding, and the tertiary-side lead wire of the tertiary winding are arranged on the same side and the counter electrode at the center of the concentric circle A method for manufacturing a molded-type instrument transformer, characterized in that the high-voltage-side lead wires are arranged at the top of the center of a concentric circle, the height being substantially the same at a position. In the manufacturing method of the molded-type instrument transformer as described in any one of Claims 5-7,
In the in-mold installation step, a method for manufacturing a molded instrument transformer, wherein an insulating laminate is interposed between a ground-side lead wire, a secondary-side lead wire, or a tertiary-side lead wire. In the manufacturing method of the transformer for mold type instruments according to any one of claims 1 to 8,
In the forming step, a solid insulator having an epoxy resin as a main component is formed as an insulating resin, and the method for manufacturing a molded instrument transformer is characterized. In the manufacturing method of the transformer for molded instruments according to claim 9,
The insulating resin is
A cycloaliphatic epoxy resin as the main agent,
Phthalic anhydride as a curing agent,
An organometallic complex as a curing accelerator;
Fused quartz as filler,
A method for manufacturing a molded-type instrument transformer, characterized by comprising a solid insulator for outdoor use. In the manufacturing method of the transformer for mold type instruments according to any one of claims 1 to 10,
In the molding step,
Having a first coating agent application step of applying a water repellent coating agent on the release agent layer applied to the inner surface of the mold before filling with the insulating resin;
A method for producing a molded-type instrument transformer, characterized by curing a water-repellent coating agent together with an insulating resin. In the manufacturing method of the transformer for mold type instruments according to any one of claims 1 to 11,
In the molding step,
Having a second coating agent coating step of covering the surface of the insulating resin which has been released from the mold and cured after filling with the insulating resin with a water repellent coating agent,
A method for producing a molded-type instrument transformer, characterized by curing a water-repellent coating agent together with an insulating resin. In the manufacturing method of the molded-type instrument transformer of Claim 11 or Claim 12,
In the first coating agent application step and / or the second coating agent application step, a silicone-based or fluorine-based water-repellent coating agent is cured to form a water-repellent coating layer. Manufacturing method. The solid insulator for a molded instrument transformer manufactured based on the method for manufacturing a molded instrument transformer according to any one of claims 1 to 13,
An insulating body that covers the winding and the iron core with an insulating resin;
A high-pressure side bushing that covers the high-voltage side lead wire and the high-voltage side terminal with an insulating resin, is provided in a substantially cylindrical shape along the high-voltage side lead wire, and has a concavo-convex crease in the central axial section;
A low-pressure side bushing that covers the ground-side lead wire and the ground-side terminal with an insulating resin, is provided in a substantially cylindrical shape along the ground-side lead wire, and has a concavo-convex fold portion in the cross section in the central axis direction;
The secondary lead wire and secondary terminal extending in a direction substantially parallel to the central axis are coated with insulating resin, or the secondary lead wire, tertiary lead wire, and secondary extending in a direction substantially parallel to the central axis. A terminal block covering the side terminal and the tertiary side terminal with an insulating resin and projecting in a substantially truncated cone shape;
A molded instrument transformer, characterized in that is formed.

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