The present disclosure relates to a spark coil.
An internal-combustion engine represented by an engine for automobiles includes a spark coil for applying high voltage to a spark plug. The spark coil includes: a center core having the shape of a quadrangular prism; a primary coil disposed on an outer peripheral side of the center core; a secondary coil disposed on an outer peripheral side of the primary coil; and side cores disposed at both ends of the center core. The spark coil is a transformer composed of these components. Each side core is disposed on an outer side of the secondary coil. These components are electrically connected to a connector module and an output terminal. Then, the components are, together with the connector module and the output terminal, secured by means of an insulating resin and fixed inside a case. The connector module has a connector to be connected to a vehicle harness. The output terminal is connected to the spark plug of the internal-combustion engine via a spring.
In general, each of the center core and the side core is made of electromagnetic steel sheets that are stacked on each other. As the insulating resin, a thermosetting resin such as epoxy resin is used. The secondary coil includes a tubular secondary bobbin and a secondary conductive wire wound around the secondary bobbin. The output terminal is electrically connected to the secondary conductive wire. In the spark coil, it is important to assuredly connect the output terminal and the secondary conductive wire to each other when the components are secured by means of the insulating resin and fixed inside the case. A spark coil has been disclosed in order to address this problem. The spark coil includes a lead terminal on an output terminal side and a lead terminal on a secondary conductive wire side. The lead terminals are bent so as to be capable of being fitted to each other. In this spark coil, a bent portion of the lead terminal on the secondary conductive wire side is press-fitted into a secondary bobbin, and, at the time of assembling, a bent portion of the lead terminal on the output terminal side is fitted to the bent portion of the lead terminal on the secondary conductive wire side so that electrical connection between the output terminal and the secondary conductive wire is ensured (see, for example, Patent Document 1).
However, since the conventional spark coil requires the two lead terminals, i.e., the lead terminal on the output terminal side and the lead terminal on the secondary conductive wire side, a drawback arises in that the number of components is large so that cost is high. Further, since the temperature of the internal-combustion engine greatly changes, the lead terminals of the spark coil repetitively undergo thermal expansion and thermal shrinkage owing to repetitive changes in the temperature of the internal-combustion engine. Since the bent portion of the lead terminal on the secondary conductive wire side is press-fitted into the secondary bobbin in the conventional spark coil, the repetitive thermal expansion and thermal shrinkage of the said lead terminal cause drawbacks in that: the lead terminal is separated from the secondary bobbin; and a crack is generated in the secondary bobbin.
The present disclosure has been made to solve the above drawbacks, and an object of the present disclosure is to provide a spark coil that requires low cost, and that can inhibit separation of a lead terminal from a secondary bobbin and inhibit generation of cracks in the secondary bobbin.
A spark coil according to the present disclosure includes: a center core; a primary coil disposed on an outer periphery of the center core; a secondary coil disposed on an outer periphery of the primary coil; and an output terminal electrically connected to the secondary coil. The secondary coil includes a tubular secondary bobbin having a plurality of flanges on an outer peripheral side thereof, a secondary conductive wire wound around the secondary bobbin, and a long-sheet-shaped secondary lead terminal having one end portion electrically connected to the secondary conductive wire and having another end portion electrically connected to the output terminal. The secondary lead terminal is disposed between corresponding ones of the flanges so as to be in surface contact with none of side surfaces of the flanges.
In the spark coil according to the present disclosure, the secondary coil includes the tubular secondary bobbin having the plurality of flanges on the outer peripheral side thereof, the secondary conductive wire wound around the secondary bobbin, and the long-sheet-shaped secondary lead terminal having the one end portion electrically connected to the secondary conductive wire and having the other end portion electrically connected to the output terminal. The secondary lead terminal is disposed between the corresponding flanges so as to be in surface contact with none of the side surfaces of the flanges. Consequently, the spark coil requires low cost, and can inhibit separation of the secondary lead terminal from the secondary bobbin and inhibit generation of cracks in the secondary bobbin.
Hereinafter, spark coils according to embodiments for carrying out the present disclosure will be described in detail with reference to the drawings. In the drawings, the same or corresponding portions are denoted by the same reference characters.
Each of the center core 3 and the side cores 6 is made of, for example, electromagnetic steel sheets that are stacked on each other. Each of the primary conductive wire 42 and the secondary conductive wire 52 is made of, for example, a copper wire. Each of the primary bobbin 41 and the secondary bobbin 51 is made of a resin. The secondary lead terminal 53 is made of, for example, a metal such as brass, iron, copper, nickel, or stainless steel. The magnet 7 is magnetized in a direction opposite to a direction of a magnetic flux generated by electrical conduction to the primary coil 4. Each side core 6 has an O shape or a C shape so as to form a closed magnetic path together with the center core 3 and the magnet 7. Each core cover 9 is formed so as to cover at least a part of the corresponding side core 6. The core cover 9 is obtained by insert molding together with the side core 6, or molded as a component that is separate from the side core 6. The ignitor 21 includes a switching control circuit that causes and interrupts electrical conduction to the primary coil 4. The connector terminal 22 is fastened to an engine harness. The insulating resin 11 is, for example, a thermosetting epoxy resin.
In the spark coil configured as described above, the secondary lead terminal 53 is disposed between the corresponding flanges 511 so as to be in surface contact with none of the side surfaces of the flanges 511. Thus, even if the secondary lead terminal 53 repetitively undergoes thermal expansion and thermal shrinkage owing to repetitive changes in the temperature of the internal-combustion engine, the spark coil according to the present embodiment can inhibit separation of the secondary lead terminal 53 from the secondary bobbin 51 and inhibit generation of cracks in the secondary bobbin 51 since the secondary lead terminal 53 is apart from the secondary bobbin 51.
It is noted that the ribs each having a triangular cross section are formed on the side surfaces of the flanges in the present embodiment. Protrusions that are alternatives to the ribs may be protrusions with any shapes as long as the protrusions are line-shaped protrusions that are in line contact with the secondary lead terminal. Further, the ribs are formed on the side surfaces of the flanges of the secondary bobbin in the present embodiment. Alternatively, the ribs may be formed on surfaces, of the secondary lead terminal, that face the flanges. Moreover, a noise-preventing resistance element may be used as the output terminal in the spark coil according to the present embodiment.
In the spark coil according to the first embodiment, the line-shaped protrusions are formed on the side surfaces of the corresponding flanges of the secondary bobbin, and the secondary lead terminal is in line contact with the flanges so that the secondary lead terminal is fixed. Meanwhile, in a spark coil according to a second embodiment, the secondary lead terminal is in point contact with the flanges so that the secondary lead terminal is fixed.
The configuration of the spark coil according to the present embodiment is similar to the configuration of the spark coil according to the first embodiment. The spark coil according to the present embodiment includes a secondary bobbin in which, unlike in the secondary bobbin in the first embodiment, conical protrusions are formed instead of the ribs formed on the side surfaces of the flanges. The coupling portion of the secondary lead terminal is disposed between the flanges so as to be fixed by being sandwiched between the conical protrusions. Thus, the coupling portion of the secondary lead terminal is not in surface contact with the flanges but is in point contact with the flanges. Judging from this, the conical protrusions can be referred to also as needle-shaped protrusions.
In the spark coil configured as described above, the secondary lead terminal is disposed between the corresponding flanges so as to be in surface contact with none of the side surfaces of the flanges. Thus, even if the secondary lead terminal repetitively undergoes thermal expansion and thermal shrinkage owing to repetitive changes in the temperature of the internal-combustion engine, the spark coil according to the present embodiment can inhibit separation of the secondary lead terminal from the secondary bobbin 51 and inhibit generation of cracks in the secondary bobbin 51.
It is noted that the conical protrusions are formed on the side surfaces of the flanges in the present embodiment. Protrusions that are alternatives to the conical protrusions may be protrusions with any shapes as long as the protrusions are needle-shaped protrusions that are in point contact with the secondary lead terminal. Further, in the present embodiment, the needle-shaped protrusions are formed on the side surfaces of the flanges of the secondary bobbin. Alternatively, the needle-shaped protrusions may be formed on the surfaces, of the secondary lead terminal, that face the flanges.
The configuration of the spark coil according to the present embodiment is similar to the configuration of the spark coil according to the first embodiment. The spark coil according to the present embodiment is, unlike the spark coil according to the first embodiment, provided with a gap between the secondary lead terminal and a body portion of the secondary bobbin. As shown in
In the spark coil configured as described above, a path to be filled with the insulating resin having fluidity is obtained between the secondary bobbin and the secondary lead terminal when the secondary coil is fixed inside the case together with the insulating resin. Thus, the gap between the secondary bobbin and the secondary lead terminal is assuredly filled with the insulating resin having fluidity at the time of producing the spark coil. As a result, voids or the like do not remain inside the insulating resin that has been cured, whereby voltage endurance characteristics of the spark coil are improved. In particular, the path to be filled with the insulating resin can be assuredly obtained also between the ribs 512 by, as shown in
It is noted that, in order to obtain the path to be filled with the insulating resin, only either of the cut portion 513 on the secondary bobbin 51 side and the cut portion 534 on the secondary lead terminal 53 side has to be formed.
Although the disclosure is described above in terms of exemplary embodiments, it should be understood that the various features, aspects, and functionality described in the embodiments are not limited in their applicability to the particular embodiment with which they are described, but instead can be applied alone or in various combinations to the embodiments of the disclosure.
It is therefore understood that numerous modifications which have not been exemplified can be devised without departing from the scope of the specification of the present disclosure. For example, at least one of the constituent components may be modified, added, or eliminated.
Number | Date | Country | Kind |
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2021-170079 | Oct 2021 | JP | national |