JP2006242123A - Ignition coil - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ignition coil capable of restricting intrusion of water into a plug hole. <P>SOLUTION: This ignition coil 1 is fixed by inserting it into the plug hole 52 provided so as to pass through the inner peripheral part of a ring-like projection part 51 projected like a ring from an engine head cover 5, and has a flange surface part 35 and a seal rubber 6. A first annular passage 72 is formed between the seal rubber 6 and the flange surface part 35, and a second annular passage 74 is formed between an inner tube part 61 and an outer tube part 62 of the seal rubber 6. An axial communication passage 71 is formed between the seal rubber 6, a cylindrical part 2 and the flange surface part 35, and the seal rubber 6 is formed with an inside communication passage 73 and an outside communication passage 75. The ignition coil 1 is structured possible to form a ventilation passage 7 for ventilating gas inside the plug hole 52 outside through the axial communication passage 71, the first annular passage 72, the inside communication passage 73, the second annular passage 74, and the outside communication passage 75 in this order. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an ignition coil for generating a spark from a spark plug.

  For example, as shown in FIG. 14, the ignition coil 91 used to generate a spark in a spark plug in an engine of a vehicle or the like penetrates the inner peripheral portion of a ring-shaped projecting portion 951 projecting in a ring shape from the engine head cover 95. Is inserted and fixed in a plug hole 952 provided in the. The ignition coil 91 has a cylindrical portion 92 having a primary coil and a secondary coil wound concentrically, and a plug attachment for attaching an ignition plug is attached to the tip of the cylindrical portion 92. A portion is formed (not shown). By attaching the spark plug to the plug mounting portion, the ignition coil 91 and the spark plug are electrically connected within the plug hole 952.

The plug hole 952 has an opening 953 that opens to the outside of the engine head cover 95, and the opening 953 is closed by a flange surface portion 935 provided below the coil head portion 93. A ring-shaped seal rubber 96 externally inserted into the cylindrical portion 92 is interposed between the flange surface portion 935 and the ring-shaped protrusion 951 of the engine head cover 95 so that external water or the like does not enter. .
In such an ignition coil 91, ozone gas, blow-by gas (unburned gas), etc. are generated in the plug hole 952 by energization of the ignition coil 91 and the ignition plug by a high-voltage current. Therefore, a ventilation passage 97 for ventilating the gas to the outside without completely sealing the inside of the plug hole 952 is provided.

  That is, as shown in FIG. 14, in the ignition coil 91, between the seal rubber 96 and the flange surface portion 935, the annular passage 972 and the annular passage 972 that allow fluid to flow in the circumferential direction therebetween communicate with the outside. An external communication path 973 is formed. In addition, an axial communication path 971 that connects the inside of the plug hole 952 and the annular path 972 is formed between the seal rubber 96 and the cylindrical portion 92 and the flange surface portion 935 by providing a groove in the cylindrical portion 92. Yes. A ventilation passage 97 is formed in which the gas inside the plug hole 952 passes through the axial communication passage 971, the annular passage 972, and the external communication passage 973 in order to be ventilated to the outside.

  However, the ignition coil 91 has a negative pressure as compared with the outside of the engine head cover 95 due to the contraction of the air inside the plug hole 952 during engine cooling. Then, due to the generation of the negative pressure, water is sucked into the ventilation passage 97 from the outside and enters the plug hole 952. In particular, when the ventilation passage 97 is short or has a structure that allows water to easily flow, the water that has entered the ventilation passage 97 easily flows into the plug hole 952. When water enters the plug hole 952, it is difficult to ensure electrical connection between the ignition coil 91 and the spark plug, and the engine may not be operated normally.

  In order to solve the above problem, for example, Patent Document 1 proposes a structure in which a waterproof wall that covers the outer periphery of the vent passage (air vent hole) outlet is provided so as to prevent water from entering the plug hole. . However, with the above structure, it is difficult to completely prevent water from entering the ventilation passage, and the water that has entered the ventilation passage may easily flow into the plug hole.

JP-A-9-112402

  The present invention has been made in view of such conventional problems, and an object of the present invention is to provide an ignition coil capable of suppressing the intrusion of water into a plug hole.

The present invention is an ignition coil that is inserted and fixed in a plug hole provided so as to penetrate an inner peripheral portion of a ring-shaped protruding portion that protrudes in a ring shape from an engine head cover,
A cylindrical portion having a primary coil and a secondary coil wound concentrically, a plug mounting portion for mounting a spark plug formed at the tip of the cylindrical portion, and the ring-shaped protruding portion so as to face each other A flange surface portion provided at the rear end portion of the cylindrical portion, and a seal rubber that is extrapolated to the cylindrical portion and interposed between the flange surface portion and the ring-shaped protruding portion,
Between the seal rubber and the flange surface portion, a first annular passage is formed between the two so that fluid can flow in the circumferential direction.
The seal rubber has an inner tube portion and an outer tube portion facing the inner peripheral surface and the outer peripheral surface of the ring-shaped protrusion, respectively.
The inner pipe part and the outer pipe part are continuous on the flange surface part side,
Between the inner tube portion and the outer tube portion, a second annular passage is formed that can store the ring-shaped protrusion and can circulate fluid in the circumferential direction,
Between the seal rubber and the cylindrical portion and the flange surface portion, an axial communication path is formed to communicate the inside of the plug hole and the first annular passage,
The seal rubber is formed with an internal communication path that communicates the first annular path and the second annular path, and an external communication path that communicates the second annular path and the outside,
The gas inside the plug hole forms a ventilation passage through which the axial communication passage, the first annular passage, the internal communication passage, the second annular passage, and the external communication passage are sequentially ventilated. The ignition coil is configured to be possible (Claim 1).

In the ignition coil of the present invention, the gas inside the plug hole sequentially passes through the axial communication passage, the first annular passage, the internal communication passage, the second annular passage, and the external communication passage to the outside. The ventilation passage to be ventilated can be formed.
That is, the space formed in the circumferential direction between the inner tube portion and the outer tube portion of the seal rubber, which has not been conventionally used as a ventilation passage, that is, the second annular passage in the present invention is used as the ventilation passage. Used as part of Therefore, the ventilation passage can be secured longer, and at the same time, the volume of the entire ventilation passage can be increased.

  Thus, the ignition coil can reduce the possibility that water that has entered the ventilation passage due to the negative pressure generated inside the plug hole reaches the plug hole when the engine is cooled. Further, even when the ignition coil is flooded with a large amount of water, there is little possibility that water entering the ventilation passage fills the entire ventilation passage and reaches the plug hole. Further, since the ventilation passage does not hinder the flow of gas due to the increase in length, the gas inside the plug hole smoothly flows through the ventilation passage and ventilates outside as in the conventional case. can do.

  As described above, according to the present invention, it is possible to provide an ignition coil capable of suppressing the entry of water into the plug hole.

In the present invention, the external communication passage is preferably provided in a radial direction so as to open to the outer peripheral surface of the outer tube portion.
In this case, the infiltration of water into the external communication path can be suppressed. Even when water enters the external communication path, the external communication path is provided in the radial direction from the outer peripheral surface of the outer pipe portion. It can be suppressed from flowing in.

Further, it is preferable that the external communication path is provided in the axial direction so as to open at a front end face of the outer pipe portion facing the engine head cover.
That is, the front end surface of the outer tube portion where the external communication passage is open faces the lower side in the axial direction. Therefore, it is possible to suppress water from entering the external communication path. Even when water enters the external communication path, the external communication path is provided upward in the axial direction from the distal end surface of the outer pipe portion. It can suppress flowing into the inside of a communicating path.

Moreover, it is preferable that the said external communicating path is a structure where a cross-sectional area becomes small gradually as it approaches the exterior (Claim 4).
In this case, since it becomes difficult to suck water into the external communication path, it is possible to further suppress the intrusion of water into the external communication path.

In addition, the outer tube portion is provided with a protruding portion that protrudes outward, and the external communication path is preferably provided through the protruding portion or adjacent to the protruding portion. Item 5).
In this case, the flow of water that travels along the outer pipe portion and moves into the external communication path can be cut off by the protrusion. Therefore, it is possible to further suppress water intrusion into the external communication path.

Further, the seal rubber has a plurality of ring-shaped rib portions that abut against the flange surface portion, and is configured to form the first annular passage between the plurality of rib portions. (Claim 6).
In this case, since the plurality of rib portions abut against the flange surface portion, the sealing performance of the first annular passage formed between the seal rubber and the flange surface portion can be sufficiently ensured. . Therefore, it is possible to reliably prevent water from directly entering the first annular passage from the outside, and to smoothly circulate the gas inside the plug hole and vent the outside.

In addition, it is preferable that the axial communication path and the internal communication path, and the internal communication path and the external communication path are formed so as not to overlap with each other in the circumferential direction (Claim 7).
In this case, the water that has entered the ventilation passage cannot easily flow from the external communication passage to the internal communication passage or from the internal communication passage to the axial communication passage. That is, the water that has entered the ventilation passage cannot easily flow through the ventilation passage, and it is difficult to reach the plug hole.

Further, the seal rubber has an enlarged end formed so as to protrude toward the inner peripheral surface of the ring-shaped protrusion at the tip of the inner tube, and the ring-shaped protrusion at the tip of the outer tube. It is preferable to have a reduced diameter end portion formed so as to protrude toward the outer peripheral surface of the portion.
In this case, the ring-shaped projecting portion can be sandwiched from the inside and outside by the diameter-expanded end portion and the diameter-reduced end portion, and the first portion formed between the outer tube portion and the inner tube portion. A sufficient sealing property of the two annular passages can be ensured. Therefore, it is possible to reliably prevent water from directly entering the second annular passage from the outside, and to smoothly circulate the gas inside the plug hole and vent the outside.

Example 1
An ignition coil according to an embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 1, the ignition coil 1 of this example is inserted and fixed in a plug hole 52 provided so as to penetrate through an inner peripheral portion of a ring-shaped protruding portion 51 protruding in a ring shape from the engine head cover 5. The ignition coil 1 includes a cylindrical part 2 having a primary coil 21 and a secondary coil 22 wound concentrically, a plug attachment part 41 for attaching a spark plug formed at the tip part 201 of the cylindrical part 2, A flange surface portion 35 provided at the rear end portion 202 of the cylindrical portion 2 so as to face the ring-shaped protruding portion 51, and is interposed between the flange surface portion 35 and the ring-shaped protruding portion 51 while being extrapolated to the cylindrical portion 2. The sealing rubber 6 is provided.

As shown in FIGS. 2 to 5, a first annular passage 72 is formed between the seal rubber 6 and the flange surface portion 35 so as to allow fluid to flow in the circumferential direction therebetween.
Further, the seal rubber 6 is an inner tube portion facing the inner peripheral surface (ring-shaped protruding portion inner peripheral surface) 511 of the ring-shaped protruding portion 51 and the outer peripheral surface (ring-shaped protruding portion outer peripheral surface) 512 of the ring-shaped protruding portion 51. 61 and the outer pipe part 62, and the inner pipe part 61 and the outer pipe part 62 are continued on the flange surface part 35 side. Between the inner tube portion 61 and the outer tube portion 62, a second annular passage 74 is formed that can accommodate the ring-shaped protruding portion 51 and can circulate fluid in the circumferential direction.

Further, as will be described later, the seal rubber 6 and the cylindrical portion 2 and the flange surface portion 35 are connected in the axial direction to communicate the inside of the plug hole 52 and the first annular passage 72 by a groove provided in the cylindrical portion 2. A passage 71 is formed. In addition, the seal rubber 6 is formed with an internal communication path 73 that allows the first annular path 72 and the second annular path 74 to communicate with each other, and an external communication path 75 that allows the second annular path 74 to communicate with the outside.
As shown in FIG. 6, the gas inside the plug hole 52 sequentially passes through the axial communication path 71, the first annular path 72, the internal communication path 73, the second annular path 74, and the external communication path 75 to the outside. The ventilation passage 7 that is ventilated by the air can be formed.
This will be described in detail below.

As shown in FIG. 1, the ignition coil 1 of the present example inserts the cylindrical portion 2 into a plug hole 52 provided so as to penetrate the inner peripheral portion of the ring-shaped protruding portion 51 protruding in a ring shape from the engine head cover 5. It is configured as follows.
The cylindrical portion 2 is formed by inserting an outer peripheral core 23, a primary coil 21, a secondary coil 22, and a central core 24 into a coil case 20. The primary coil 21 is formed by winding an insulation-coated wire around the outer peripheral surface of a primary spool 211 made of cylindrical resin, and the secondary coil 22 is primary on the outer peripheral surface of a secondary spool 221 made of cylindrical resin. It is formed by winding a wire coated with an insulation with a greater number of turns than the coil 21. The primary coil 21 may be formed by winding a wire with an insulation coating in a cylindrical shape and then bonding the wound wires together with a fusing agent or the like to form a cylindrical shape.

  The primary coil 21 is inserted in a cylindrical metal outer core 23, and the outer core 23 is inserted in the coil case 20. The secondary coil 22 is inserted on the inner peripheral side of the primary coil 21, and a rod-shaped metal central core 24 is disposed on the inner peripheral side of the secondary coil 22. The magnetic flux generated by passing a current through the primary coil 21 can be increased by passing through the central core 24 and the outer peripheral core 23.

The central core 24 is formed by laminating a plurality of steel plates (for example, silicon steel plates) in the radial direction in order to suppress the generation of eddy currents due to the formation of magnetic flux generated by passing a current through the primary coil 21. Further, permanent magnets 241 for further increasing the magnetic flux generated by the primary coil 21 are disposed at both axial ends of the central core 24.
In addition, an insulating resin 29 is filled in each gap between the central core 24 and the secondary coil 22, between the secondary coil 22 and the primary coil 21, and between the primary coil 21 and the outer core 23. Yes. In this example, an epoxy resin is used as the insulating resin 29.

  A coil head portion 3 is formed at the rear end portion 202 of the cylindrical portion 2, and an igniter 32 that supplies power to the primary coil 21 is disposed in the igniter case 31. The igniter case 31 is filled with an insulating resin 29 with the igniter 32 disposed. The igniter 32 includes a power control circuit using a switching element or the like that operates in response to a signal from an ECU (electronic control unit), an ion current detection circuit that detects an ion current, and the like.

On the other hand, a plug attachment portion 41 for attaching a spark plug is formed at the distal end portion 201 of the cylindrical portion 2. The plug mounting portion 41 is provided with a coil spring 42 that comes into contact with the spark plug. The coil spring 42 is electrically connected to the high voltage side end of the secondary coil 22 via a high voltage terminal 43. Yes.
When a spark generation signal is transmitted from the ECU to the igniter 32, a switching element or the like in the igniter 32 operates to cause a current to flow through the primary coil 21, and accordingly, the secondary coil 22 is induced by electromagnetic induction. Electric power (back electromotive force) is generated, and a spark can be generated from the spark plug attached to the plug attachment portion 41 of the ignition coil 1.

The coil head portion 3 protrudes radially outward and includes a bolt mounting portion 33 formed with a bolt insertion hole 331 through which a tightening bolt screwed into the engine head cover 5 is inserted, and radially outward. And a connector portion 34 that protrudes and is electrically connected to the outside of the ignition coil 1.
The bolt mounting portion 33 in the coil head portion 3 faces the engine head cover 5, a fastening bolt is inserted into the bolt insertion hole 331, and this fastening bolt is screwed into a screw hole formed in the engine head cover 5. Thus, the ignition coil 1 is attached to the engine head cover 5.

  As shown in FIG. 2, the coil head portion 3 is provided with a flange surface portion 35 having a diameter larger than that of the cylindrical portion 2 so as to face the ring-shaped protruding portion 51 of the engine head cover 5. The opening 521 of the plug hole 52 is closed by the flange surface portion 35, and a ring-shaped seal rubber 6 extrapolated to the cylindrical portion 2 is interposed between the flange surface portion 35 and the ring-shaped protrusion 51. It is installed.

  Further, as shown in the figure, a ring-shaped first rib portion 63 is formed to protrude in the circumferential direction on the seal rubber upper surface portion 601 facing the flange surface portion 35 of the seal rubber 6. In addition, a plurality of ring-shaped second rib portions 64 are formed along the seal rubber first outer peripheral surface 603 on the seal rubber first outer peripheral surface 603 that is an outer peripheral surface continuous with the seal rubber upper surface portion 601. Also, a cylindrical protrusion 65 is provided on the seal rubber second outer peripheral surface 604 that is continuous with the seal rubber first outer peripheral surface 603 in the axial direction so as to protrude outward.

  Further, as shown in the figure, the flange surface portion 35 has a concave portion 36 and a convex portion 37 formed outside the concave portion 36 in the circumferential direction. A first rib portion 63 formed on the seal rubber upper surface portion 601 is in contact with a concave bottom surface 361 that is the bottom surface of the concave portion 36. A plurality of second rib portions 64 formed on the seal rubber first outer peripheral surface 603 is in contact with the convex inner peripheral surface 371 which is the inner peripheral surface of the convex portion 37. Further, a seal rubber step portion 602 that connects the seal rubber first outer peripheral surface 603 and the seal rubber second outer peripheral surface 604 is in contact with the convex portion front end surface 372 that is the front end surface of the convex portion 37.

  As shown in FIGS. 2 and 3, a first annular passage 72 is formed between the seal rubber 6 and the flange surface portion 35 to allow fluid to flow in the circumferential direction. The first annular passage 72 sufficiently secures the sealing performance by the first rib portion 63 in contact with the concave bottom surface 361 and the second rib portion 64 in contact with the convex inner circumferential surface 371.

  As shown in FIG. 2, the seal rubber 6 has an inner tube portion 61 and an outer tube portion 62 that face the ring-shaped protruding portion inner peripheral surface 511 and the ring-shaped protruding portion outer peripheral surface 512, respectively. It continues in the surface 35 side. Further, the seal rubber 6 includes an enlarged diameter end portion 611 formed so as to protrude toward the ring-shaped protruding portion inner peripheral surface 511 at the distal end portion of the inner tube portion 61, and a ring-shaped protruding portion at the distal end portion of the outer tube portion 62. And a reduced diameter end portion 621 formed so as to protrude toward the outer peripheral surface 512.

Further, as shown in the figure, a ring-shaped protrusion 51 is accommodated between the inner tube portion 61 and the outer tube portion 62 of the seal rubber 6. Further, the enlarged diameter end portion 611 of the inner tube portion 61 is in contact with the inner peripheral surface 511 of the ring-shaped protruding portion, and the reduced diameter end portion 621 of the outer tube portion 62 is in contact with the outer peripheral surface 512 of the ring-shaped protruding portion. Has been.
As shown in FIGS. 2 and 4, a second annular passage 74 capable of circulating fluid in the circumferential direction is formed between the inner tube portion 61 and the outer tube portion 62. The second annular passage 74 sufficiently secures the sealing performance by the enlarged diameter end portion 611 abutted on the ring-shaped protruding portion inner peripheral surface 511 and the reduced diameter end portion 621 abutted on the ring-shaped protruding portion outer peripheral surface 512. ing.

Further, as shown in FIG. 2, the seal rubber second outer peripheral surface 604 is formed with the above-described cylindrical protrusion 65 protruding outward.
As shown in FIGS. 2 and 4, the outer tube portion 62 of the seal rubber 6 has an external communication passage 75 that penetrates the outer tube portion 62 and the protrusion 65 and communicates the second annular passage 74 with the outside. It is formed in the radial direction. The external communication path 75 has a ventilation port 751 formed so as to open to the outside.

As shown in FIGS. 2 to 4, an internal communication path 73 that connects the first annular path 72 and the second annular path 74 is formed in the axial direction at a circumferential position facing the protrusion 65.
Further, as shown in FIGS. 3 and 5, at a circumferential position different from the internal communication path 73, the seal rubber inner circumferential surface 605, which is the inner circumferential surface of the seal rubber 6, and the cylindrical portion 2, and the seal rubber first Between the upper surface portion 601 and the flange surface portion 35, an axial communication passage 71 that connects the inside of the plug hole 52 and the first annular passage 72 is formed. The axial communication path 71 is formed by providing a groove in the axial direction on the outer peripheral surface 203 of the cylindrical portion, which is the outer peripheral surface of the cylindrical portion 2, and contacting the outer peripheral surface 203 of the cylindrical portion and the inner peripheral surface 605 of the seal rubber.

As described above, the ignition coil 1 of the present example includes the axial communication passage 71, the first annular passage 72, the internal communication passage 73, the second annular passage 74, and the external communication passage 75 as shown in FIG. A ventilation passage 7 is formed for communicating the inside and the outside of the plug hole 52.
As shown in the figure, the gas inside the plug hole 52 flows through the ventilation passage 7 in the order of the axial communication passage 71, the first annular passage 72, the internal communication passage 73, the second annular passage 74, and the external communication passage 75. The air is ventilated to the outside through the ventilation port 751. Further, in order for external water to reach the plug hole 52, the water must flow along the reverse route to the gas vented to the outside.

In addition, in this example, FIG.3 and FIG.4 represents only the ventilation channel | path 7 in the AA cross section and BB cross section of FIG. FIG. 3 shows a cross-sectional shape of the first annular passage 72 and an axial communication passage 71 and an internal communication passage 73 communicated with the first annular passage 72. FIG. 4 shows the cross-sectional shape of the second annular passage 74 and the internal communication passage 73 and the external communication passage 75 communicated with the second annular passage 74.
FIG. 6 shows the ventilation passage 7 in a simplified manner, and shows how the gas inside the plug hole 52 is ventilated to the outside.

Next, the effect in the ignition coil 1 of this example is demonstrated.
In the ignition coil 1 of this example, the gas inside the plug hole 52 sequentially passes through the axial communication passage 71, the first annular passage 72, the internal communication passage 73, the second annular passage 74, and the external communication passage 75 to the outside. The ventilation passage 7 that is ventilated by the air can be formed.
In other words, the space formed in the circumferential direction between the inner tube portion 61 and the outer tube portion 62 of the seal rubber 6 that has not been used as a ventilation passage in the past, that is, the second annular passage 74 in this example is used as the ventilation passage 7. Used as part of Therefore, the ventilation passage 7 can be secured longer and, at the same time, the volume of the entire ventilation passage 7 can be increased.

  Thereby, the ignition coil 1 can reduce the possibility that the water that has entered the ventilation passage 7 due to the negative pressure generated inside the plug hole 52 reaches the plug hole 52 when the engine is cooled. Further, even when the ignition coil 1 is flooded with a large amount of water, the water that has entered the ventilation passage 7 fills the entire ventilation passage 7 and is less likely to reach the plug hole 52. In addition, since the ventilation passage 7 is not hindered by the increase in length, the gas inside the plug hole 52 smoothly flows through the ventilation passage 7 and ventilates outside as in the conventional case. can do.

  Further, in this example, the external communication passage 75 is provided in the radial direction so as to open to the seal rubber second outer peripheral surface 604 of the outer tube portion 62. That is, the external communication passage 75 has a ventilation port 751 that opens to the seal rubber second outer peripheral surface 604 of the outer tube portion 62, and is provided in the radial direction inside the outer tube portion 62. Therefore, water can be prevented from entering the external communication path 75. Further, even when water enters the external communication path 75, it is possible to suppress the intruded water from flowing into the external communication path 75 due to gravity.

  Further, the internal communication path 73 is provided in the axial direction so as to communicate the first annular path 72 and the second annular path 74. In other words, in order for the water that has entered the ventilation passage 7 to flow from the second annular passage 74 to the first annular passage 72, the water must flow in the internal communication passage 73 against the gravity upward in the axial direction. Don't be. Therefore, the water that has entered the ventilation passage 7 cannot easily flow through the ventilation passage 7, and it becomes difficult to reach the plug hole 52.

In addition, the outer pipe portion 62 is provided with a protruding portion 65 protruding outward, and the external communication path 75 is provided so as to penetrate the protruding portion 65. Therefore, the protrusion 65 can cut off the flow of water that travels around the ventilation port 751 along the outer pipe 62. Therefore, it is possible to further suppress the intrusion of water into the external communication path 75.
The external communication path 75 may be provided adjacent to the protrusion 65. In this case, the same effect as described above can be obtained.
Moreover, as shown in FIG. 7, it can also be set as the structure which does not provide the projection part 65 in the outer tube | pipe part 62. FIG. Even in this case, it is possible to sufficiently obtain the effect of suppressing the entry of water from the ventilation port 751 into the external communication path 75.

  The seal rubber 6 is formed with a plurality of ring-shaped rib portions 63 and 64 that abut against the flange surface portion 35, and a first annular passage 72 is formed between the plurality of rib portions 63 and 64. It is configured. That is, the first rib portion 63 and the second rib portion 64 can sufficiently secure the sealing performance of the first annular passage 72 formed between the seal rubber 6 and the flange surface portion 35. Therefore, it is possible to reliably prevent water from directly entering the first annular passage 72 from the outside, and to smoothly circulate the gas inside the plug hole 52 and vent the outside.

Further, the axial communication path 71 and the internal communication path 73 and the internal communication path 73 and the external communication path 75 are formed so as to be shifted so that their circumferential positions do not overlap each other. That is, in order for the water that has entered the ventilation passage 7 to flow from the external communication passage 75 to the internal communication passage 73, it must pass through the second annular passage 74 that connects both passages. Further, in order to flow from the internal communication path 73 to the axial direction communication path 71, it must pass through the first annular path 72 that similarly connects both the paths. Therefore, the water that has entered the ventilation passage 7 cannot easily flow through the ventilation passage 7, and it becomes difficult to reach the plug hole 52.
In addition, the ventilation path 7 can be ensured longest by making the circumferential direction position of the axial direction communication path 71 and the external communication path 75 the same, and forming the internal communication path 73 in the circumferential position facing both.

  The seal rubber 6 includes an enlarged diameter end portion 611 formed to protrude toward the ring-shaped protruding portion inner peripheral surface 511 at the distal end portion of the inner tube portion 61, and an outer periphery of the ring-shaped protruding portion at the distal end portion of the outer tube portion 62 And a reduced diameter end portion 621 formed so as to protrude toward the surface 512. In other words, the enlarged diameter end portion 611 and the reduced diameter end portion 621 can sufficiently secure the sealing performance of the second annular passage 74 formed between the inner tube portion 61 and the outer tube portion 62. Therefore, it is possible to reliably prevent water from entering directly into the second annular passage 74 from the outside, and to smoothly circulate the gas inside the plug hole 52 and vent the outside.

  Thus, according to this example, it is possible to provide an ignition coil capable of suppressing the entry of water into the plug hole.

(Example 2)
This example is an example in which the shape of the external communication path 75 is changed in the ignition coil 1 of the first embodiment, as shown in FIGS.
As shown in FIG. 8, the external communication passage 75 of the present example is provided in the axial direction so as to open to the outer tube front end surface 620 facing the engine head cover 5 of the outer tube 62. That is, the external communication path 75 has a ventilation port 751 that opens to the distal end surface 620 of the outer tube portion 62, and is provided in the axial direction inside the outer tube portion 62.
Other basic configurations are the same as those in the first embodiment.

In this case, the intrusion of water into the external communication path 75 can be suppressed. Even when water enters the external communication path 75, the external communication path 75 is provided upward in the axial direction from the ventilation port 751. It can be suppressed from flowing in.
Further, even when the external communication path 75 is provided in the radial direction as in the first embodiment, an even greater effect can be obtained.
The other functions and effects are the same as those of the first embodiment.

Further, as shown in FIG. 9, in addition to the above-described configuration, a protrusion 65 can be provided on the outer tube front end surface 620 and the external communication path 75 can be formed through the protrusion 65.
In this case, in addition to the above-described operational effects, the operational effects obtained by providing the protrusions 65 can be obtained.

(Example 3)
This example is an example in which the shape of the external communication path 75 is changed in the ignition coil 1 of the second embodiment, as shown in FIGS.
As shown in FIG. 10, the external communication path 75 of the present example has a ventilation port 751 that opens to the outer tube portion distal end surface 620, and the reduced diameter end portion 621 of the outer tube portion 62 and the ring-shaped protruding portion outer peripheral surface 512. Are provided in the axial direction.
The rest of the configuration is the same as that of the second embodiment and has the same functions and effects.

Further, as shown in FIG. 11, in addition to the above-described configuration, a waterproof wall 66 that is formed so as to protrude from the outer pipe front end surface 620 toward the engine head cover 5 and covers the periphery of the ventilation port 751 can be provided. .
In this case, in addition to the above-described effects, water that moves around the ventilation port 751 can be prevented by the waterproof wall 66.

Example 4
This example is an example in which the shape of the protrusion 65 is changed in the ignition coil of Example 1 as shown in FIGS.
As shown in FIGS. 12A and 12B, the protrusion 65 can be provided adjacent to the ventilation port 751 of the external communication path 75 and at a part of the periphery of the ventilation port 751.
The other configuration is the same as that of the first embodiment, and has the same operation and effect.

Further, as shown in FIG. 13, the projecting portion 65 may have a structure in which the cross-sectional area gradually decreases as it approaches the tip portion of the projecting portion 65. Further, along with this, the external communication path 75 formed through the protrusion 65 may have a structure in which the cross-sectional area gradually decreases as it approaches the ventilation port 751.
In this case, it becomes difficult to suck water from the ventilation port 751. Therefore, it is possible to suppress water from entering the external communication path 75.
The other configuration is the same as that of the first embodiment, and has the same operation and effect.

FIG. 3 is an explanatory diagram illustrating the structure of an ignition coil in the first embodiment. The enlarged view which shows the seal rubber periphery part of an ignition coil in Example 1. FIG. AA arrow sectional drawing of FIG. BB arrow sectional drawing of FIG. CC sectional view taken on the line of FIG. FIG. 3 is an explanatory view showing a ventilation passage in the first embodiment. Explanatory drawing which shows the shape of the other external communicating path in Example 1. FIG. Explanatory drawing which shows the shape of the other external communicating path in Example 2. FIG. Explanatory drawing which shows the shape of the other external communicating path in Example 2. FIG. Explanatory drawing which shows the shape of the other external communicating path in Example 3. FIG. Explanatory drawing which shows the shape of the other external communicating path in Example 3. FIG. In Example 4, (a) Explanatory drawing which shows the shape of other protrusion parts, (b) Explanatory drawing which shows the shape of the protrusion part seen from the outside. Explanatory drawing which shows the shape of the other projection part in Example 4. FIG. The enlarged view which shows the seal rubber periphery part of the conventional ignition coil.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Ignition coil 2 Cylindrical part 35 Flange surface part 5 Engine head cover 51 Ring-shaped protrusion part 52 Plug hole 6 Seal rubber 61 Inner pipe part 62 Outer pipe part 7 Ventilation passage 71 Axial direction communication path 72 1st annular path 73 Internal communication path 74 1st 2-annular passage 75 External communication passage

Claims (8)

An ignition coil inserted and fixed in a plug hole provided so as to penetrate the inner peripheral portion of the ring-shaped projecting portion projecting in a ring shape from the engine head cover,
A cylindrical portion having a primary coil and a secondary coil wound concentrically, a plug mounting portion for mounting a spark plug formed at the tip of the cylindrical portion, and the ring-shaped protruding portion so as to face each other A flange surface portion provided at the rear end portion of the cylindrical portion, and a seal rubber that is extrapolated to the cylindrical portion and interposed between the flange surface portion and the ring-shaped protruding portion,
Between the seal rubber and the flange surface portion, a first annular passage is formed between the two so that fluid can flow in the circumferential direction.
The seal rubber has an inner tube portion and an outer tube portion facing the inner peripheral surface and the outer peripheral surface of the ring-shaped protrusion, respectively.
The inner pipe part and the outer pipe part are continuous on the flange surface part side,
Between the inner tube portion and the outer tube portion, a second annular passage is formed that can store the ring-shaped protrusion and can circulate fluid in the circumferential direction,
Between the seal rubber and the cylindrical portion and the flange surface portion, an axial communication path is formed to communicate the inside of the plug hole and the first annular passage,
The seal rubber is formed with an internal communication path that communicates the first annular path and the second annular path, and an external communication path that communicates the second annular path and the outside,
The gas inside the plug hole forms a ventilation passage through which the axial communication passage, the first annular passage, the internal communication passage, the second annular passage, and the external communication passage are sequentially ventilated. An ignition coil characterized by being configured.   2. The ignition coil according to claim 1, wherein the external communication path is provided in a radial direction so as to open to an outer peripheral surface of the outer tube portion.   2. The ignition coil according to claim 1, wherein the external communication path is provided in an axial direction so as to open at a front end surface of the outer pipe portion facing the engine head cover.   The ignition coil according to any one of claims 1 to 3, wherein the external communication path has a structure in which a cross-sectional area gradually decreases as it approaches the outside.   5. The outer tube portion according to claim 1, wherein the outer tube portion is provided with a protruding portion that protrudes outward, and the external communication path penetrates the protruding portion or is adjacent to the protruding portion. An ignition coil characterized by being provided.   6. The seal rubber according to claim 1, wherein a plurality of ring-shaped rib portions abutting on the flange surface portion are formed to protrude from the seal rubber, and the first annular ring is formed between the plurality of rib portions. An ignition coil configured to form a passage.   7. The axial communication passage and the internal communication passage, and the internal communication passage and the external communication passage are formed so as to be shifted so that circumferential positions do not overlap with each other. Features an ignition coil.   8. The seal rubber according to claim 1, wherein the seal rubber includes a diameter-expanded end formed so as to project toward an inner peripheral surface of the ring-shaped projecting portion at a distal end portion of the inner tube portion, An ignition coil comprising: a reduced diameter end portion formed so as to protrude toward an outer peripheral surface of the ring-shaped protruding portion at a distal end portion of the tube portion.

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