Source: https://patents.google.com/patent/JP6215556B2/en
Timestamp: 2020-01-20 13:35:14
Document Index: 682394660

Matched Legal Cases: ['arts 21', 'arts 1', 'art 21', 'art 2', 'art 21', 'art 21', 'art 22', 'art 82']

JP6215556B2 - Reactor - Google Patents
JP6215556B2
JP6215556B2 JP2013074694A JP2013074694A JP6215556B2 JP 6215556 B2 JP6215556 B2 JP 6215556B2 JP 2013074694 A JP2013074694 A JP 2013074694A JP 2013074694 A JP2013074694 A JP 2013074694A JP 6215556 B2 JP6215556 B2 JP 6215556B2
JP2013074694A
JP2014199866A (en
2013-03-29 Application filed by 株式会社タムラ製作所 filed Critical 株式会社タムラ製作所
2013-03-29 Priority to JP2013074694A priority Critical patent/JP6215556B2/en
2014-03-19 Priority claimed from US14/219,863 external-priority patent/US9343223B2/en
2014-10-23 Publication of JP2014199866A publication Critical patent/JP2014199866A/en
2017-10-18 Publication of JP6215556B2 publication Critical patent/JP6215556B2/en
The present invention relates to a reactor having an improved arrangement of sensor connectors.
As a reactor used in an in-vehicle booster circuit, a coil is wound around a resin bobbin placed around the core, then housed in a metal case, and filled with a filler into the case. Is often used.
One of these types of reactors has a structure in which a plurality of split cores are combined to form an annular core, and coils are wound around the left and right legs. Each divided core is embedded in the resin, and the resin portion is a core cover or a coil bobbin. In general, a molding method is employed to arrange the resin around the core.
In this type of reactor, if a high current continues to flow, the coil will overheat and its electrical characteristics will deteriorate, so the internal temperature is measured by a temperature sensor such as a thermistor, and energization control is performed so that the coil does not generate heat above a certain temperature. Made.
When arranging a sensor in a reactor, in order to perform accurate temperature detection, it is necessary to arrange a sensor in the vicinity of a coil or a core that becomes a heating element. Therefore, the structure which arrange | positions a sensor between right and left coils like patent document 1 and patent document 2 conventionally was employ | adopted. According to this prior art, since the sensor can be arranged at the center portion of the reactor, there is an advantage that the temperature detection accuracy is excellent.
JP 2010-203998 A JP 2012-243913 A
By the way, in the reactor which has this kind of sensor, the connector for connecting the lead wire from a sensor and the wiring inside a vehicle is needed. This connector is required to have a certain size in order to ensure the insulation of the connecting portion and to enable easy connection by hand. At the same time, when using the reactor, it is necessary to fix the connector using some holder so that the connector does not move due to vibration or the like.
In a reactor in which a core as described above is molded into a resin, it is easy to provide a protrusion or a recess for locking the connector on the resin portion as a holder for this type of connector. However, when performing molding, the position and shape of the holder are also limited by the shape of the mold to be used and the position and shape of the core disposed inside the resin. The reason is demonstrated with reference to the conventional reactor shown in FIG.7 and FIG.8.
In this type of reactor, the bobbin 102 is provided on the outer periphery of the left and right leg portions of the annular core 101, and the coil 103 is wound around the outer periphery. The yoke portion of the core 101 around which the coil 103 is not wound is covered with a cover 104 formed integrally with the bobbin 102. Between the left and right bobbins 102, a support plate 105 for holding the sensor is provided integrally with the bobbin 102. In the vicinity of the bobbin 102 of the cover 104, a locking portion 106 for hooking the sensor lead wire is provided.
In this type of reactor, in order to arrange the bobbin 102 around the core 101, a mold forming method is generally used in which the core 101 is arranged in a mold and a resin is injected into the mold around the core 101 and solidified. To do. In this case, if there is a gap between the mold surface and the core 101, the resin enters the gap and becomes a burr after molding. In particular, in the prior art, since the core 101 is brought into contact with the bottom surface of the aluminum case 108 that houses the reactor and heat is directly radiated from the core 101, if there is a burr, a gap is generated between the case 108 and the core 101, Heat transfer is reduced. Therefore, in the prior art, the gap between the mold surface and the core 101 is eliminated by pressing with a spring from above the core 101 to prevent the generation of burrs.
As described above, in order to press the core 101 from above, it is necessary to bring the spring and the core 101 into contact with each other. In the prior art, an opening 107 having no resin is formed in the upper part of the cover 104 that covers the core 101 to position the core 101 in the mold. However, if there is an opening 107 at the top of the core 101, it is impossible to provide a holder for the connector at that portion. Therefore, the holder is molded with resin so as to project to the side of the core 101, or a reactor is attached. A holder is provided in a part of the case 108 to be stored.
Such a holder provided on the side of the core 101 increases the lateral dimension of the reactor, which hinders miniaturization. In addition, the conventional technique in which the core is pressed against the surface of the mold when the resin is filled is not preferable because a pressurizing mechanism is provided separately from the mold and the structure of the mold becomes complicated.
The present invention has been proposed to solve the above-described problems of the prior art. The present invention integrally molds the holder on the upper part of the core, thereby enabling a reduction in the size of the reactor and eliminating the need to press the core against the mold surface. The purpose is to provide a reactor that can simplify the work.
The present invention provides a reactor including an annular core, a coil wound around the outer periphery of a leg portion of the annular core, a sensor for detecting a state of the reactor, and a connector for outputting a signal of the sensor. Around the periphery, there is a resin molded product in which an annular core is embedded, and in the resin molded product, a covering portion that contacts and covers the coil bobbin and the core is integrally formed with the resin of the resin molded product. An exposed portion where the resin does not cover the bottom of the core is formed on the lower surface of the covering portion, and a holder for fixing the sensor connector is integrally formed with the resin on the upper portion of the covering portion. It is formed, It is characterized by the above-mentioned.
As the holder, an appropriate configuration such as a slide type, a fitting type, or a hook type can be adopted according to the shape of the connector to be fixed thereby.
According to the present invention, since it is not necessary to press the core against the mold at the time of molding, the holder can be integrally formed with the resin above the core. As a result, the reactor can be reduced in size by arranging the holder and the connector fixed by the holder above the core. In addition, a mechanism for pressing the core against the mold becomes unnecessary, and the number of manufacturing steps of the reactor can be reduced.
The disassembled perspective view of the reactor of 1st Embodiment. The perspective view which looked at the reactor of FIG. 1 from the right front. The perspective view which looked at the reactor of FIG. 1 from the right rear. The perspective view which looked at the state which attached the connector to the reactor of FIG. 1 from the right front. The perspective view which looked at the state which attached the connector to the reactor of FIG. 1 from the right rear. Sectional drawing of the reactor of FIG. The perspective view which shows an example of the conventional reactor. Sectional drawing which shows an example of the conventional reactor.
(1) Configuration The reactor according to the present embodiment has an annular core 1, and the annular core 1 includes two U-shaped cores 1 a and 1 b that constitute the yoke portion, and left and right leg portions. It consists of three I-shaped cores 1c. The U-shaped cores 1a and 1b and the I-shaped core 1c are connected via a spacer 1d.
The annular core 1 is covered with two resin molded products 2 and 3 on the bobbin side and terminal side provided on the outer periphery thereof. The bobbin-side molded product 2 has cylindrical left and right bobbins 22a and 22b, and a core coating portion 21 provided so as to connect these. A first U-shaped core 1a is embedded in the covering portion 21 by a molding method. In each of the left and right bobbins 22a and 22b, three I-shaped cores 1c are inserted from the opening at the tip of the bobbin. The molded product 3 on the terminal side is provided with a core covering portion 31, in which a second U-shaped core 1b is embedded by a molding method.
Openings 21a and 31a used for holding the U-shaped cores 1a and 1b in the mold during molding are provided on the outer surfaces of the covering portions 21 and 31, respectively. The surface of internal U-shaped cores 1a and 1b is exposed at 31a. There is no resin at the bottoms of the covering parts 21 and 31 to set the U-shaped cores 1a and 1b on the mold surface, and the exposed parts 1e where the bottoms of the U-shaped cores 1a and 1b appear. . However, in this embodiment, since the U-shaped cores 1a and 1b are not pressed against the mold surface from above, there is a possibility that a resin that becomes a burr exists in this portion.
Metal fittings 23 and 33 for fixing the annular core 1 to the case 4 are embedded in the covering portions 21 and 31 on the bobbin side and the terminal side. The tips of the metal fittings 23 and 33 protrude from the surfaces of the covering portions 21 and 31, and screw insertion holes 24 and 34 for fixing the annular core 1 to the case 4 are provided in the portions. By fastening the screws 41 a and 41 b inserted into the screw insertion holes 24 and 34 into the screw holes 42 a and 42 b of the case 4, the annular core 1 and the case 4 are fixed.
Support plates 25 and 35 for holding the sensor are provided inside the bobbin-side and terminal-side covering portions 21 and 31 so as to be sandwiched between the left and right bobbins 22a and 22b. Each of the support plates 25 and 35 is a triangular member, and the sensor 6 is inserted into the gap between the two when the annular core 1 is assembled. The lead wire 61 of the sensor 6 is pulled out to the bobbin side covering portion 21 side, and a connector 62 is connected to the tip thereof.
The left and right coils 51a and 51b are wound around the outer circumferences of the bobbins 22a and 22b. These left and right coils 51a and 51b are formed of a single conductor, and both ends thereof are drawn out toward the terminal-side covering portion 31. Grooves 36a and 36b for inserting the ends of the coils 51a and 51b are integrally formed in the terminal-side cover 31.
A resin terminal block 71 is provided on the outside of the terminal-side cover 31 separately from the terminal block 71. The terminal block 71 is provided with two recesses 72a and 72b, and metal terminals 73a and 73b are respectively fixed inside thereof. Part of the terminals 73a and 73b rises upward, and ends of the coils 51a and 51b are connected to the rising portions. The terminal block 71 is provided with a screw insertion hole 74, and the terminal block 71 is fixed to the case 4 by fastening the screw 43 inserted into the screw insertion hole 74 into the screw hole 44 of the case 4.
The holder 8 of the connector 62 is formed integrally with the covering portion 21 on the upper portion of the covering portion 21 on the bobbin side. The holder 8 may have any shape as long as it can fix the connector 62 to the covering portion 21. In the present embodiment, the following is adopted according to the shape of the connector 62.
As shown in FIGS. 2 and 3, a vertically rising wall 81 is provided at a portion on the bobbin side of the upper surface of the covering portion 21, and a locking portion 81 a for hooking a sensor lead wire to the upper edge of the wall 81. Is provided. A block 82 is formed integrally with the wall 81 adjacent to the locking portion 81a, and two upper and lower guides 83a and 83b extending at right angles to the axial direction of the bobbin are parallel to the block 82 at a constant interval. Is provided. The upper and lower guides 83 a and 83 b are members having an L-shaped cross section, and the vertical portions thereof are slidably inserted into the two grooves 63 a and 63 b provided in the connector 62. Between the upper and lower guides 83a and 83b, there is provided a hook 84 having a base end fixed to the block 82 and a free end. The tip of the hook 84 engages with a convex portion 64 provided between the two grooves 63 a and 63 b of the connector 62.
The annular core 1, the resin molded products 2 and 3, and the left and right coils 51 a and 51 b having the above-described configuration are housed in the case 4 in an assembled state, and the metal fittings 23 and 33 are screwed to the case 4. Fixed to. In this case, the resin molded products 2 and 3 and the left and right coils 51 a and 51 b are fixed so that a predetermined gap is maintained between the outer periphery of the case 4 and the inner surface of the case 4. By filling the gap 9 with a filler 9 and solidifying, the case 4 and the annular core 1 assembled are integrated.
(2) Effects According to the first embodiment having the above-described configuration, as shown in the cross-sectional view of FIG. 6, the U-shaped cores 1a and 1b exposed at the bottoms of the covering portions 21 and 31 are provided. The bottom portion (exposed portion 1e) is covered with the filled material 9 filled. As a result, even if there is a resin that has become the bottom burr of the U-shaped cores 1a and 1b at the time of molding, the portion is covered with the filler 9, and no trouble occurs. On the other hand, since it is not necessary to provide an opening in the upper part of the covering part 21, the holder 8 can be provided in that part and the connector 62 can be fixed. As a result, the connector 62 can be accommodated within the planar projection range of the resin molded product 2 and the reactor can be reduced in size.
2. Other Embodiments The present invention is not limited to the above-described embodiments, and includes other embodiments described below.
(1) In the above embodiment, since the connector is large with respect to the reactor, the connector is arranged at right angles to the axial direction of the bobbin. However, if the connector is small, it is parallel to the axial direction of the bobbin. A holder can also be provided.
(2) In the above-described embodiment, the entire connector is within the plane projection range of the resin molded product 2, but a part of the connector protrudes from the plane projection range of the resin molded product 2, or around the case You may protrude from.
(3) As the core, a combination of two U-shaped cores in a ring shape or a combination of two U-shaped cores and a plurality of I-shaped cores in a ring shape can be used. It is also possible to use a core in which a central leg is provided on an annular core in parallel with the left and right leg portions, and a coil is wound around that portion. What comprised the cyclic | annular core from one member may be sufficient.
(4) Although the I-shaped core is fitted and fixed inside the bobbin, the I-shaped core may be embedded in the molded product 2 by a molding method like the U-shaped core.
(5) In addition to the temperature sensor, a sensor that detects other physical quantities can be used as the sensor.
(6) As the shape of the holder, a groove, a recess, a through hole, or the like for inserting the entire connector can be used. It is also possible to form a holder by providing a hook or a recess on the connector side and a protrusion or hook engaged therewith. When the connector is fixed with a band or a wire, a hole through which the band passes can be used as a holder. A holder can also be provided in a resin molded product provided with a terminal block.
(7) As the case, a metal case other than aluminum or a resin case excellent in thermal conductivity can be used. As for the shape of the case, in addition to a box shape having an open upper surface as shown in the figure, a dish shape having a shallow edge or a plate shape may be used. In addition, implementation of only the annular core, the resin molded product, and the coil assembly without using resin for the case or the gap between the cases is also an embodiment of the present invention.
(8) The connector in the present invention is not limited to the illustrated configuration. It is a member that connects the sensor lead wire and external wiring, and includes all shapes that need to be fixed to the reactor, for example, a fitting type, a sliding type, and a joining structure by welding or fastening. It can also be applied to a reactor in which a plurality of connectors are provided on one reactor.
DESCRIPTION OF SYMBOLS 1 ... Ring core 1a, 1b ... U-shaped core 1c ... I-type core 1d ... Spacer 1e ... Exposed part 2, 3 ... Resin molded part 21, 31 ... Cover part 21a, 31a ... Opening part 22a, 22b ... Bobbin 23, 33 ... Metal fittings 24, 34 ... Screw insertion holes 25, 35 ... Support plates 36a, 36b ... Groove 4 ... Cases 41a, 41b, 43 ... Screws 42a, 42b, 44 ... Screw holes 51a, 51b ... Coil 6 ... Sensor 61 ... Lead Wire 62 ... Connector 63a, 63b ... Groove 64 ... Projection 71 ... Terminal block 72a, 72b ... Recess 73a, 73b ... Terminal 74 ... Insertion hole 8 ... Holder 81 ... Wall 81a ... Locking part 82 ... Block 83a, 83b ... Guide 84 ... Hook 9 ... Filler
A coil wound around the outer periphery of the leg of the annular core;
A sensor for detecting the state of the reactor;
In a reactor equipped with a connector that outputs the signal of this sensor,
Around the annular core is provided with a resin molded product in which the annular core is embedded,
In the resin molded product, a coating portion that covers and covers the periphery of the bobbin of the coil and the core is integrally formed with the resin of the resin molded product ,
On the lower surface of the covering portion, an exposed portion where the resin does not cover the bottom of the core is formed,
On the upper part of the covering portion, a holder for fixing the connector of the sensor is integrally formed with the resin,
The reactor according to claim 1, wherein an assembly including a resin molded product in which the annular core is embedded and a coil wound around the bobbin is housed in a case.
The gap according to claim 2, wherein a gap is formed between the assembly and the case, and the gap is filled with a filler and solidified, and the exposed portion of the core bottom is covered with the filler. Reactor.
The annular core includes two U-shaped cores, and the resin molded products include terminal-side and bobbin-side resin molded products in which the U-shaped cores are embedded,
The reactor according to any one of claims 1 to 3, wherein a pair of left and right bobbins and the holder are integrally formed on the resin molded product on the bobbin side.
A block is formed on the upper surface of the covering portion, a guide extending perpendicular to the axial direction of the bobbin is provided on the block, a connector is inserted into the guide, and a hook whose base end is fixed to the block is provided on the block. The reactor according to any one of claims 1 to 4, wherein the hook is engaged with a connector.
JP2013074694A 2013-03-29 2013-03-29 Reactor Active JP6215556B2 (en)
US14/219,863 US9343223B2 (en) 2013-03-29 2014-03-19 Reactor
JP2014199866A JP2014199866A (en) 2014-10-23
JP6215556B2 true JP6215556B2 (en) 2017-10-18
ID=52356607
JP2013074694A Active JP6215556B2 (en) 2013-03-29 2013-03-29 Reactor
JP (1) JP6215556B2 (en)
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