KR101246086B1 - Ignition trans - Google Patents

Abstract

PURPOSE: An ignition transformer is provided to restrain a circuit part, a case, and so on from being contaminated or damaged by epoxy forming a mold layer in case of production process, thereby improving quality-safety. CONSTITUTION: An ignition transformer(1) includes an ignition coil part(30), a circuit part(20), and a case(10). The ignition coil part is formed by winding a primary coil and a secondary coil on a ferrite core, and boosts the low voltage of input current to a high voltage according to winding ratio, and then instantaneously outputs the input current through an output line. The circuit part applies the low voltage of the input current to the ignition coil part. The case, the upper side of which is opened, is partitioned into a first housing space for housing the ignition coil part and a second housing space for housing the circuit part by a partitioning piece.

Description

Ignition trans}

The present invention relates to an ignition transformer, and more particularly, a high voltage installed in a combustion device that obtains energy by burning fuel such as petroleum, diesel, and gas and boosts a low voltage current applied through an input line to a high voltage and is induced. The present invention relates to an ignition transformer that distributes the discharge to an output line.

In general, a combustion device that generates heat through combustion of a combustion product such as petroleum, diesel, and gas, for example, a boiler, is configured to ignite the combustion product by instantaneously discharging a high voltage to an ignition rod in a combustion chamber.

The high voltage that is instantaneously discharged to the ignition rod for the ignition of the fuel rod is implemented through an ignition transformer for boosting the commercial AC power (110V to 220V) to a high voltage and instantaneously discharging the ignition rod.

The ignition transformer has a form in which a primary side coil and a secondary side coil are wound to a ferrite core at a predetermined ratio, and the voltage is boosted at a high voltage according to the turns ratio of the primary side coil and the secondary side coil to ignite through the output line. An ignition coil unit for instant discharge with a rod; The circuit part for applying low voltage input current to the ignition coil part is built in the case.

In addition, the ignition coil part is required to have a stable insulation structure because high voltage is induced, and in the art, the ignition coil part and the circuit part are separately charged into a pair of accommodating spaces partitioned by partition pieces in the enclosure, and the ignition coil Epoxy is injected into the accommodating space to ensure stable insulation of the ignition coil part by epoxy.

However, in forming the mold layer by filling epoxy into the accommodating space accommodating the ignition coil part, when the epoxy is excessively filled and the epoxy flows out into the accommodating space accommodating the circuit part, epoxy is applied to the surface of the circuit part in which the contact point is formed and the ignition nose The problem that the contact part of a part and a circuit part became difficult to form was raised.

In addition, the epoxy flows out through the output line lead-out hole formed in the outer wall of the case, the epoxy on the outer wall of the case and the surface of the output line has a problem that the appearance and quality of the product is lowered.

An object of the present invention devised to solve the above problems is to propose and adopt an improved ignition coil part, to ensure improved insulation and assemblability, while the circuit part or case by an epoxy forming a mold layer in the production process It is to provide an ignition transformer to prevent the back from being contaminated or damaged to have improved quality stability.

The above object is achieved by the following constitutions provided in the present invention.

Ignition transformer according to the present invention,

An ignition coil unit having a primary coil and a secondary coil wound around a ferrite core, respectively, boosting to a high voltage according to the turns ratio of the primary coil and the secondary coil, and outputting them instantaneously to an output line; A circuit unit for applying a low voltage input current to the ignition coil unit; And an upper opening case in which a first accommodating space accommodating the ignition coil part and a second accommodating space accommodating the circuit part are partitioned by the partition pieces to accommodate the ignition coil part and the circuit part compartmentally.

The ignition coil unit, and an auxiliary case; A coil bundle accommodated in the auxiliary case; And a mold layer including a mold layer which is injected and cured in the auxiliary case in which the coil bundle is accommodated, and fixes the coil bundle contained in the auxiliary case in an insulating structure, and is configured to be installed by charging in a first accommodation space formed in the case. It is characterized by.

Preferably, the ignition coil unit may form a mold layer made of epoxy under a reduced pressure in the auxiliary case accommodating the coil bundle, and the air remaining in the auxiliary case may be decompressed during the process of forming a mold layer made of epoxy in the auxiliary case. It is configured to be discharged to the outside by.

More preferably, the single type ignition coil unit; In the case of the upper open type in which the circuit parts forming the contacts are partitioned in the accommodation spaces, the surface mold layers made of Homica are stacked.

A connector is formed between the second accommodating space accommodating the circuit part and the outer wall of the case, so that the power supply part is connected to the circuit part through a connector formed on the outer wall of the case.

As described above, in the present invention, a single bundle type ignition coil unit is formed by charging the coil bundle in a separate auxiliary case and then fixing the coil bundle in an insulating structure through a mold layer made of epoxy. A part and a circuit part are partitioned in each accommodating space of a case.

In this way, when the unit type ignition coil unit is charged into the housing of the case, the case, the circuit unit, the output line, and the like can be prevented from being contaminated by the epoxy during the molding of the coil bundle through the epoxy. A more stable insulation state of the coil bundle can be secured by the auxiliary case.

In addition, since the single type ignition coil part is put into the drying furnace alone in the manufacturing process and rapidly dried, damage to the circuit part due to dry drying can be suppressed.

Particularly, in the present invention, in forming an mold layer by injecting epoxy into the auxiliary case in which the coil bundle is accommodated, the mold layer is implemented under a reduced pressure. Accordingly, the epoxy injected into the auxiliary case is formed without forming voids on the surface of the coil bundle. It can be fixed stably and can exhibit improved insulation.

1 to 3 show the assembling and coupling states respectively showing the overall configuration of the ignition transformer proposed as a preferred embodiment of the present invention,
4 to 6 is a manufacturing state diagram sequentially showing the manufacturing process of the ignition coil in the ignition transformer proposed in the preferred embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the ignition transformer proposed in the preferred embodiment of the present invention.

1 to 3 show the assembly and the coupling state respectively showing the overall configuration of the ignition transformer proposed as a preferred embodiment in the present invention, Figures 4 to 6 is an ignition proposed as a preferred embodiment in the present invention In the transformer, a manufacturing state diagram showing the manufacturing process of the ignition coil unit in sequence.

The ignition transformer 1 according to the present invention, as shown in Figures 1 to 3, the ignition coil unit 30 for boosting the low-voltage input current to output to the ignition rod through the output line 50; A circuit unit 20 for applying a low-voltage input current applied from a power supply unit (not shown) to the ignition coil unit 30; It is configured to include a case 10 for accommodating the ignition coil unit 30 and the circuit unit 20 partitioned.

The case 10 has an upper opening type in which a first accommodating space 12 in which the ignition coil part 30 is accommodated and a second accommodating space 13 in which the circuit part 20 is accommodated are partitioned by a partition piece 11. It is composed of a housing, and accommodates the ignition coil section 30 and the circuit section 20, respectively.

Referring to the drawings, an output line outlet 12a communicating with the outside is formed on the upper side of the first accommodating space 12 in which the ignition coil part 30 is accommodated, and a second accommodating space in which the circuit part 20 is accommodated ( 13 and the outer wall of the case 10 as shown in Figure 1, the connector 14 is formed so that the input line 40 of the power supply (not shown) through the connector 14 formed on the outer wall of the case 10 It is simply connected to the circuit unit 20 and configured to apply a current.

In addition, the upper part of the partition piece 11 is formed with a terminal fixing groove (11a) is fixed to the output end of the circuit portion and the input end of the ignition coil portion, so that the output end and the input end of the circuit portion to be interconnected to be shaped by the terminal fixing grooves Configured to be deployed.

In addition, the ignition coil unit 30 accommodated in the first accommodating space 12 has a primary coil 31b and a secondary coil 31c in a ferrite core 31a as shown in FIG. 4. The coil bundle 31 which is wound around each of the coils 31 for boosting the low-voltage current applied from the circuit unit 20 to a high voltage according to the turns ratio of the primary coil 31b and the secondary coil 31c and outputting them to the output line 50. It is configured to include.

Referring to the drawings, the coil bundle 31 has a series type in which secondary coils 31c are arranged on both left and right sides of the primary coil 31b, and the low-voltage input current input from the primary coil 31b is The secondary coils 31c disposed on both sides are induced and stepped up and output through the output line 50.

Meanwhile, in the present embodiment, the coil bundle 31 is charged directly into the first accommodating space 12 of the case 10 and is not adhered through a mold layer made of epoxy. The bundle 31 is charged and configured as a single piece fixed through a mold layer 33 made of epoxy, so that it is installed in the first receiving space 12 of the case 10.

When the single type ignition coil unit 30 is charged in the first receiving space 12 of the case 10 as in this embodiment, the output line, the case, and the case are charged in the molding process of the coil bundle through epoxy. The phenomenon in which the used circuit portion and the like are contaminated by epoxy can be prevented, and a more stable insulation state of the ignition coil portion can be ensured by the auxiliary case.

In the present embodiment, the auxiliary case 32 formed of epoxy in the auxiliary case 32 accommodating the coil bundle 31 is formed under a reduced pressure, and the auxiliary case is formed in the process of forming the mold layer 33 made of epoxy. Air remaining in (32) is discharged to the outside by the depressurization action.

As such, when the air remaining in the auxiliary case 32 is discharged, the mold layer 33 made of epoxy is closely adhered to the surface of the coil bundle 31 without voids, thereby improving the settling of the coil bundle 31. Ensure insulation.

In detail, as shown in FIG. 5, the auxiliary case 32 containing the coil bundle 31 is accommodated in the decompression chamber 100 at a pressure lower than atmospheric pressure. At this time, each of the input terminals 31b-a and the output terminals 31c-a formed in the coil bundle 31 are drawn out to the upper portion of the auxiliary case 32 so that the epoxy injected into the surface does not adhere to the surface.

Thereafter, the epoxy is primarily filled in the auxiliary case 32 by about 70% to form a primary mold layer 33a made of epoxy in the auxiliary case 32 to fix the coil bundle 31. The air remaining in the auxiliary case 32 is discharged to the outside by the decompression action of the decompression chamber 100.

Subsequently, 30% of epoxy is additionally injected into the auxiliary case 32 in the auxiliary case 32 in which the primary mold layer 33a is formed, as shown in FIG. 6A, thereby forming the auxiliary mold in which the primary mold layer 33a is formed. The secondary mold layer 33b is laminated in the case 32 to be formed.

At this time, the auxiliary case 32 filled with the epoxy for forming the first mold layer 33a and the second mold layer 33b is introduced into a drying furnace (not shown), and the property curing process of the epoxy by heating is performed. It is desirable to pass through.

The single unit type ignition coil part 30 is charged in the first accommodating space 12 of the case 10, as shown in FIGS. 1 and 2, and the output end of the circuit part 20 accommodated in the second accommodating space 13 ( 22 and the input terminals 31b-a of the ignition coil unit 30 accommodated in the first accommodation space 12 are connected to each other.

In addition, a connection terminal 14a of the connector 14 is connected to the input terminal 21 of the circuit unit 20, and an output line drawing hole formed in the case 10 at the output terminal 31c-a of the ignition coil unit 30. It is connected to the end of the output line 50 drawn out to 12a.

When the contact formation of each of the input terminals and the output terminals is completed as described above, as shown in FIG. 3, the unit type ignition coil unit 30 and the circuit unit 20 having contacts formed therein are divided into the accommodation spaces 12 and 13, respectively. In the case 10 accommodated in this case, the surface mold layer 34 is formed by laminating with Homica.

The surface mold layer 34 prevents external exposure of the ignition coil unit 30 and the circuit unit 20, while the waterproofness and insulation of the ignition coil unit 30 and the circuit unit 20 accommodated in the case 10 are prevented. Secured.

1. Ignition transformer
10. Case 11. Compartment
11a. Terminal fixing groove
12. First accommodation space 12a. Output line outlet
13. Second accommodation space 14. Connector
14a. Connection terminal
20. Circuit part 21. Input terminal
22. Output stage
30. Ignition coil part 31. Bundle of coils
31a. Ferrite core 31b. Primary coil side
31b-a. Input 31c. Secondary coil side
31c-a. Output stage 32. Auxiliary case
33. Mold layer 33a. Primary mold layer
33b. Secondary Mold Layer 34. Ferrite Mold Layer
40. Input Line 50. Output Line
100. Vacuum Chamber

Claims (4)

An ignition coil unit having a primary coil and a secondary coil wound around a ferrite core, respectively, boosting to a high voltage according to the turns ratio of the primary coil and the secondary coil, and outputting them instantaneously to an output line; A circuit unit for applying a low voltage input current to the ignition coil unit; And an upper opening case in which a first accommodating space accommodating the ignition coil part and a second accommodating space accommodating the circuit part are partitioned by the partition pieces to accommodate the ignition coil part and the circuit part compartmentally.
The ignition coil unit, and an auxiliary case; A coil bundle accommodated in the auxiliary case; And a mold layer including a mold layer which is injected and cured in the auxiliary case in which the coil bundle is accommodated, and fixes the coil bundle contained in the auxiliary case in an insulating structure, and is configured to be installed by charging in a first accommodation space formed in the case. Ignition transformer, characterized in that. The method of claim 1, wherein the ignition coil unit air formed in the auxiliary case to form a mold layer made of epoxy in the auxiliary case to form a mold layer made of epoxy in the auxiliary case accommodating the coil bundle in the auxiliary case An ignition transformer, characterized in that configured to be discharged to the outside by the decompression action. The apparatus of claim 1, further comprising: a single type ignition coil unit; An ignition transformer according to claim 1, wherein a surface mold layer made of Homica is laminated on the upper open case accommodating the circuit portions forming the contacts in the receiving spaces. The ignition transformer according to claim 1, wherein a connector is formed between the second accommodating space in which the circuit part is accommodated and the outer wall of the case so that the power supply part is connected to the circuit part through a connector formed on the outer wall of the case.

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