The present disclosure relates to a coil and a method of manufacturing a coil.
A coil is formed for example by winding a litz wire obtained by intertwining a plurality of enamel strands (thin wires) or winding a conductor such as a lower half rectangular wire having a rectangular cross section or a round wire having a circular cross section. The periphery of the conductor and the outer periphery of the coil are covered by a resin.
Patent Document 1: Japanese Patent Application Publication No. 2000-90747 A
However, degradation of the insulation property of conductors and coils lead to reduction in the performance of the coils.
Thus, there is provided a coil exhibiting excellent insulation property and a method of manufacturing such coil.
A coil of an embodiment is formed by winding a winding conductor in which a conductive conductor is molded by a resin, wherein the winding conductor has the resin filled to a surface of the conductor without leaving any spaces.
A first embodiment will be described hereinafter based on the drawings. Elements that are substantially identical in the description of the embodiments are identified with identical reference symbols and are not re-described.
A litz wire used in a coil comprises a multiconductor magnet wire (winding conductor) formed by intertwining a plurality of enamel strands (thin wire). The litz wire is being widely used as a magnet wire for coils used in high-frequency electric appliances. As the frequency of current conducted through the litz wire becomes greater, the loss becomes greater due to the increase in AC resistance caused by the skin effect.
The litz wire is used in the coils of high frequency electric appliances to suppress the increase of AC resistance by fragmenting the skin current by dividing the conductor into multiple wires using enamel lines having an insulation coating. A round litz wire having a circular cross section is generally used however, a rectangular litz wire having a rectangular cross section is also used to increase the coil occupancy when the coils of the electrical appliance are wound.
Thus, there is provided a coil having excellent insulation property and a method of manufacturing such coil.
As shown in
A strong aramid fiber tape for example is used as the lashing band 22. The lashing band 22 is shaped like a paper tape and is wound around the second unit litz wires 18 to lash the first unit litz wires 16 or the strands 14 constituting the second unit litz wires 18 so that they are not disassembled. The lashing band 22 is wound around the second unit litz wires 18 so that gaps G are formed between the wound lashing bands 22 as shown in the later described
The surrounding band 24 is wound around and covers the second unit litz wires 18 lashed by the lashing band 22. The surrounding band 24 is formed by hardening a later described nonwoven tape 32 impregnated with a later described resin liquid 38. In this case, the nonwoven tape 32 is raised as one example of a material capable of allowing penetration and permeation of the later described resin liquid 38 and capable of being wound around the second unit litz wires 18 during the later described manufacturing process flow of the coil 10. The material constituting the surrounding band 24 is not limited to the nonwoven tape 32 as long as the material possesses these properties.
In the second unit litz wires 18, insulative hardened resin 20 (resin) exists without leaving any spaces between the plurality of strands 14 or the plurality of first unit litz wires 16. The hardened resin 20 exists without leaving any spaces between the strands 14, the lashing band 22, and the surrounding band 24 and further between the first unit litz wires 16, the lashing band 22, and the surrounding band 24. That is, the second unit litz wire 18 is formed by hardening and integrally solidifying the plurality of strands 14 or the plurality of first unit litz wires 16 with the later described resin liquid 38 and is three dimensionally integrated and solidified by the hardened resin 20. Further, the litz wire 12 is obtained by solidifying the strands 14, the first unit litz wires 16, the second unit litz wires 18, the lashing band 22, and the surrounding band 24 with the hardened resin 20 without leaving any spaces. That is, the coil 10 and the litz wire 12 that constitutes the coil 10 are configured by filling and molding the hardened resin 20 between the strands 14 and in the periphery of the strands 14 without leaving any spaces.
A resin with high thermal conductivity, that is, with high heat dissipating property may be employed as the hardened resin 20, that is, the later described resin liquid 38. A resin obtained by adding a micro-sized and highly thermal conductive filler such as alumina or boron nitride to an epoxy resin for example as an additive that imparts high thermal conductivity is used as a resin having high thermal conductivity. When a resin with high thermal conductivity is employed, the coil 10 and the litz wire 12 constituting the coil 10 are configured so that hardened resin 20 with high thermal conductivity, that is, high heat dissipating property is filled between the plurality of strands 14, between the plurality of first unit litz wires 16, between the strands 14, lashing band 22, and the surrounding band 24, and further between the first unit litz wires 16, the lashing band 22, and the surrounding band 24 without leaving any spaces. Thus, because the interior of the formed coil 10 and the litz wire 12 constituting the coil 10 are filled with the hardened resin 20 having high thermal conductivity and high heat dissipating property without leaving any spaces and their outer periphery are covered by the surrounding band 24 hardened by the hardened resin 20 having high heat dissipating property, the coil 10 as a whole is caused to have high thermal conductivity and high heat dissipating property.
Next, a description will be given on a method of manufacturing the coil 10.
First, an intertwined litz wire 30a (litz wire) is prepared as shown in
Next, as shown in
Next, as shown in
The nonwoven tape 32 includes a hardening accelerator of the later described resin liquid 38. Amines, imidazoles, phosphine, DBU (1,8-diazabicyclo[5.4.0]undec-7-ene) and its organic acid salt, ammonium or phosphonium compound or the like are used as the hardening accelerator.
In case the nonwoven tape 32 is strong enough to lash the intertwined litz wire 30a, that is, strong enough to prevent the strands 14 and the first unit litz wires 16 from disassembling, it is possible to omit the lashing of the intertwined litz wire 30a by the lashing band 22. That is, it is possible to form the surrounded litz wire 30d (litz wire) shown in
Next, as shown in
After removing the coil 10b from the winding core material 34, the coil 10b is immersed in a resin container 36 filled with the resin liquid 38 as shown in
As described above, the nonwoven tape 32 includes the hardening accelerator of the resin liquid 38. The coil 10b is immersed in the resin liquid 38, and after the resin liquid 38 has permeated sufficiently into the nonwoven tape 32 and the surrounded litz wire 30c, the resin liquid 38 in the nonwoven tape 32 hardens through reaction with the hardening accelerator. Thus, the surrounding band 24 hardened by the resin is formed as shown in
Next, the coil 10d in the above described state which has been taken out of the resin container 36 is illustrated in
Next, the coil 10d is put into a heat drying furnace 42 as shown in
In the process step illustrated in
On the other hand, in order to harden the resin liquid 38 without containing the hardening accelerator in the nonwoven tape 32, the resin liquid is hardened by methods such as applying heat with the coil 10 placed inside the resin container 36. However, when such method is taken, the resin liquid 38 becomes hardened along with the resin container 36 containing the coil 10, thereby causing the coil 10 to be integrated with the resin container 36 and preventing the coil 10 from being taken out of the resin container 36. Further, the hardened resin becomes filled in the cavity in the center of the coil 10 and the cavity becomes blocked by the hardened resin. The hardening accelerator is contained in the nonwoven tape 32 to harden the resin liquid 38 in this portion alone for the above described reasons. That is, the nonwoven tape 32 turns into the surrounding band 24 hardened by the resin by containing the hardening accelerator therein and possesses a function of retaining a state in which the resin liquid 38 is filled inside the coil 10b without leaving any spaces when the coil 10b is immersed in the resin container 36 filled with the resin liquid 38 and the interior of the coil 10b is impregnated with the resin liquid 38. It is thus, possible to obtain coil 10 with improved insulation property without leaving any spaces between the strands 14, the first unit litz wires 16, the second unit litz wires 18, the lashing band 22, and the surrounding band 24 inside the coil 10.
The coil 10 according to the above described embodiment provides the following effects.
In the coil 10 of the embodiment and the litz wire 12 constituting the coil 10, the hardened resin 20 is filled and molded without leaving any spaces between the strands 14 and in the periphery of the strands 14. Thus, the insulation property of the coil 10 is improved to exert excellent insulation property even when the coil 10 is used in high frequency electric appliances for example.
Further, in the coil 10 and the litz wire 12 constituting the coil 10, the strands 14, the first unit litz wires 16, the second unit litz wires 18, the lashing band 22, and the surrounding band 24 are integrally solidified by the hardened resin 20 without leaving any spaces to provide a three-dimensionally secured structure. That is, in the coil 10 and the litz wire 12 constituting the coil 10, the hardened resin 20 is filled, solidified, and molded without leaving any spaces between the strands 14 and in the periphery of the strands 14. Thus, generation of gaps and peeling voids are suppressed in the coil 10 to provide excellent insulation property.
The periphery of the coil 10 and the litz wire 12 constituting the coil 10 of the embodiment are covered by the surrounding band 24 formed of nonwoven tape 32 hardened by the resin. Thus, the insulation property between the litz wires 12 as well as the mechanical strength of the coil 10 are improved.
In the coil 10 and the litz wire 12 constituting the coil 10 of the embodiment, a resin having high thermal conductivity, that is, high heat dissipating property may be employed as the hardened resin 20, that is, the resin liquid 38. In this case, because the coil 10 exhibits excellent heat dissipating property, it is possible to prevent damaging of the coil 10, etc. even when abnormal heat is produced for example at the coil 10.
According to the manufacturing method of the coil 10 of the embodiment, the hardening accelerator of the resin liquid 38 is contained in the nonwoven tape 32. The coil 10b being manufactured is immersed in the resin liquid 38, and the resin liquid 38 at the nonwoven tape 32 hardens through reaction with the hardening accelerator after the resin liquid 38 has sufficiently permeated into the surrounded litz wire 30c. Thus, the inner region of the coil 10 is filled with resin liquid 38 which is not hardened, that is, the unhardened resin 40 and the outer periphery of the unhardened resin 40 is covered by nonwoven tape 32 hardened by the resin liquid 38, that is, the surrounding band 24. That is, it is possible to create a situation in which the outer periphery of the unhardened resin 40 in the inner region of the coil 10 is covered by the surrounding band 24 solidified by the resin and the unhardened resin 40 is confined therein. It is thus, possible to prevent the unhardened resin 40 in the inner region of the coil 10 from leaking even when the coil 10 being manufactured is taken out of the resin container 36. As a result, it is possible to obtain the coil 10 and the litz wire 12 constituting the coil 10 in which the hardened resin 20 is filled and molded without leaving any spaces between the strands 14 and in the periphery of the strands 14. It is thus, possible to manufacture a coil 10 exhibiting excellent insulation property even when the coil 10 is applied to a high-frequency electric appliance for example.
The above description was given through an example in which a rectangular litz wire was used as the litz wire 12 of the embodiment. However, the litz wire 12 is not limited to a rectangular litz wire. A round litz wire may be used for example.
A second embodiment will be described hereinafter with reference to the drawings. In the description of the embodiment, elements that are substantially identical are identified with identical reference symbols and are not re-described.
As shown in
A strong aramid fiber tape is used for example as the lashing band 122. The lashing band 122 is shaped like a paper tape and is used to lash the strands 114 so that the strands 114 are not disassembled. As shown in the later described
The surrounding band 124 is wound around and covers the multiconductor wire 112 lashed by the lashing band 122. The surrounding band 124 is obtained by impregnating a later described nonwoven tape 132 with a later described resin liquid 138 (corresponding to liquid resin) and hardening the resin liquid 138. In this case, the nonwoven tape 132 is given as an example of a material which allows penetration and permeation of the later described resin liquid 138 and which is capable of being wound around the multiconductor wire 112 in the later described manufacturing process flow of the coil 110. The material constituting the surrounding band 124 is not limited to the nonwoven tape 132 as long as it possesses the above described properties.
An insulative hardened resin 120 (resin) exists without leaving any spaces between the plurality of strands 114. Further, the hardened resin 120 exists without leaving any spaces between the strands 114, the lashing band 122, and the surrounding band 124 as well. That is, the entirety of the coil 110 is integrated and secured three-dimensionally by the hardened resin 120 from the inside to the outside. The lashing band 122 and the surrounding band 124 are also solidified without leaving any spaces by the hardened resin 120. That is, the coil 110 and the multiconductor wire 112 constituting the coil 110 are provided with a structure in which the hardened resin 120 is filled and molded without leaving any spaces between the strands 114 and in the periphery of the strands 114.
A resin with high thermal conductivity, that is, high heat dissipating property may be employed as the hardened resin 120, that is, the later described resin liquid 138. A resin obtained by adding a micro-sized and highly thermal conductive filler such as alumina or boron nitride to an epoxy resin for example as an additive that imparts high thermal conductivity is used as a resin having high thermal conductivity. When employing a resin having a high thermal conductivity, the coil 110 and the multiconductor wire 112 constituting the coil 110 are configured so that hardened resin 120 having high thermal conductivity, that is, high heat dissipating property is filled between the plurality of strands 114, between the strands 114, the lashing band 122, and the surrounding band 124, and further to the outer peripheral surface of the coil 110. Thus, the inside of the formed coil 110 and the multiconductor wire 112 constituting the coil 110 are filled with the hardened resin 120 having high thermal conductivity, that is, high heat dissipating property without leaving any spaces, and the outer periphery of the formed coil 110 and the multiconductor wire 112 constituting the coil 110 are covered by the surrounding band 124 hardened by the hardened resin 120 having high heat dissipating property and thus, the entire coil 110 exhibits high thermal conductivity and high heat dissipation property.
Further, because there is very little amount of voids which are prone to become insulation defects and adhesion of the conductor portion and the resin is good, it is possible to obtain high insulation performance.
Next, a description will be given on the method of manufacturing the coil 110.
First, a plurality of strands 114 are prepared as illustrated in
Next, as shown in
Then, as shown in
The nonwoven tape 132 includes a hardening accelerator (corresponds to a resin hardening accelerator) of the later described resin liquid 138. Amines, imidazoles, phosphine, DBU (1,8-diazabicyclo[5.4.0]undec-7-ene) and its organic acid salt, ammonium or phosphonium compound or the like are used as the hardening accelerator.
In case the nonwoven tape 132 is strong enough to lash the strands 114, that is, strong enough to prevent the strands 114 from disassembling, it is possible to omit the lashing of the strands 114 by the lashing band 122. That is, as shown in
Next, as shown in
After removing the coil 110b from the winding core material 134, the coil 110b is immersed in a resin container 136 filled with the resin liquid 138 as shown in
As described above, the nonwoven tape 132 includes the hardening accelerator of the resin liquid 138. The coil 110b is immersed in the resin liquid 138, and after the resin liquid 138 has permeated sufficiently into the nonwoven tape 132 and the multiconductor wire 112, the resin liquid 138 in the nonwoven tape 132 hardens through reaction with the hardening accelerator. Thus, the surrounding band 124 hardened by the resin is formed as shown in the later described
Next, the coil 110d in the above described state which has been taken out of the resin container 136 is illustrated in
Next, the coil 110d is put into a heat drying furnace 142 as shown in
In the process step illustrated in
On the other hand, in order to harden the resin liquid 138 without containing the hardening accelerator in the nonwoven tape 132, the resin liquid 138 is hardened by methods such as applying heat with the coil 110 placed inside the resin container 136. However, when such method is taken, the resin liquid 138 becomes hardened along with the resin container 136 containing the coil 110, thereby causing the coil 110 to be integrated with the resin container 136 and preventing the coil 110 from being taken out of the resin container 136. Further, the hardened resin becomes filled in the cavity in the center of the coil 110 and the cavity becomes blocked by the hardened resin. The hardening accelerator is contained in the nonwoven tape 132 to harden the resin liquid 138 in this portion alone for the above described reasons. That is, the nonwoven tape 132 turns into the surrounding band 124 hardened by the resin by containing hardening accelerator in the nonwoven tape 132 and possesses a function of retaining a state in which the resin liquid 138 is filled inside the coil 110b without leaving any spaces when the coil 110b is immersed in the resin container 136 filled with the resin liquid 138 and the interior of the coil 110b is impregnated with the resin liquid 138. It is thus, possible to obtain coil 110 with improved insulation property without leaving any spaces between the strands 114, the lashing bands 122, and the surrounding bands 124 inside the coil 110.
The coil 110 according to the above described embodiment provides the following effects.
In the coil 110 and the multiconductor wire 112 constituting the coil 110 of the embodiment, hardened resin 120 is filled and molded between the strands 14 and in the periphery of the strands 14 without leaving any spaces. Thus, the insulation property of the coil 110 is improved and excellent insulation property is exerted even when the coil 110 is used in a high-frequency electric appliances for example.
Further, in the coil 110 and the multiconductor wire 112 constituting the coil 110, the strands 114, the lashing band 122, and the surrounding band 124 are integrally solidified by the hardened resin 120 without leaving any spaces to provide a three-dimensionally secured structure. That is, in the coil 110 and the multiconductor wire 112 constituting the coil 110, the hardened resin 120 is filled, solidified, and molded between the strands 114 and in the periphery of the strands 114 without leaving any spaces. Thus, generation of gaps and peeling voids are suppressed in the coil 110 to provide excellent insulation property.
The periphery of the coil 110 and the multiconductor wire 112 constituting the coil 110 of the embodiment are covered by the surrounding band 124 formed of the nonwoven tape 132 hardened by the resin. Thus, the insulation property between the multiconductor wires 112 as well as the mechanical strength of the coil 110 are improved.
In the coil 110 and the multiconductor wire 112 constituting the coil 110 of the embodiment, a resin having high thermal conductivity, that is, high heat dissipating property may be employed as the hardened resin 120, that is, the resin liquid 138. In this case, because the coil 110 exhibits excellent heat dissipating property, it is possible to prevent damaging of the coil 110, etc. even when abnormal heat is produced for example at the coil 110.
According to the manufacturing method of the coil 110 of the embodiment, the hardening accelerator of the resin liquid 138 is contained in the nonwoven tape 132. The coil 110b being manufactured is immersed in the resin liquid 138 and the resin liquid 138 at the nonwoven tape 132 hardens through reaction with the hardening accelerator after the resin liquid 138 has sufficiently permeated into the multiconductor wire 112. Thus, the inner region of the coil 110 is filled with resin liquid 138 which is not hardened, that is, the unhardened resin 140 and the periphery of the unhardened resin 140 is covered by nonwoven tape 132 hardened by the resin liquid 138, that is, the surrounding band 124. That is, it is possible to create a situation in which the periphery of the unhardened resin 140 in the inner region of the coil 110 is covered by the surrounding band 124 solidified by the resin and the unhardened resin 140 is confined therein. It is thus, possible to prevent the unhardened resin 140 of the inner region of the coil 110 from leaking even when the coil 110 being manufactured is taken out of the resin container 136. As a result, it is possible to obtain the coil 110 and the multiconductor wire 112 constituting the coil 10 in which the hardened resin 120 is filled and molded without leaving any spaces between the strands 114 and in the periphery of the strands 114. It is thus, possible to manufacture a coil 110 having excellent insulation property.
The foregoing embodiment described an example in which a rectangular line having a substantially rectangular cross section obtained by bundling two strands 114a and 114b was used, however, a single strand 114 having a substantially rectangular cross section may be used as shown in
The above description was given through an example in which a rectangular wire having a rectangular cross section was used as the multiconductor wire 112 in the embodiment. However, multiconductor wire 112 is not limited to a rectangular wire. A round wire having a circular cross section for example may be used instead.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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JP2016-039983 | Mar 2016 | JP | national |
JP2016-103315 | May 2016 | JP | national |
This application is a continuation to an International Application No. PCT/JP2016/071880, filed on Jul. 26, 2016 which is based upon and claims the benefit of priority from Japanese Patent Application No. 2016-039983, filed on, Mar. 2, 2016 and Japanese Patent Application No. 2016-103315, filed on, May 24, 2016 the entire contents of which are incorporated herein by reference.
Number | Name | Date | Kind |
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20120092108 | Prabhakaran et al. | Apr 2012 | A1 |
20140353000 | Yin | Dec 2014 | A1 |
Number | Date | Country |
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1729605 | Feb 2006 | CN |
101154848 | Apr 2008 | CN |
S 56-126807 | Sep 1981 | JP |
2000-090747 | Mar 2000 | JP |
2012-089838 | May 2012 | JP |
2013-206943 | Oct 2013 | JP |
Entry |
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English translation of JP358057711 (Year: 1983). |
Office Action in Japanese Application No. 2016-103315 dated Aug. 6, 2019. |
Chinese Office Action in CN Application No. 201680081774.6, dated Jun. 23, 2020. |
International Search Report in PCT/JP2016/071880 dated Oct. 18, 2018. |
Written Opinion in PCT/JP2016/071880 dated Oct. 18, 2018. |
English language abstract of JP 2012-089838 date May 10, 2012. |
English language abstract of JP 2013-206943 dated Oct. 7, 2013. |
English language abstract ofJP 2000-090747 dated Mar. 31, 2000. |
English language abstract of JPS 56-126807 dated Sep. 26, 1981. |
Number | Date | Country | |
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20190019606 A1 | Jan 2019 | US |
Number | Date | Country | |
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Parent | PCT/JP2016/071880 | Jul 2016 | US |
Child | 16119868 | US |