KR200205074Y1 - Coil Built-in Capacitor - Google Patents

Abstract

The present invention separates the coil part and the condenser element embedded in the case from each other so that an air vent is formed therebetween, so that the heat generated from the coil part is air-cooled by the air vent and is not transferred to the condenser element. In particular, a coil-embedded condenser, in particular, a coil-embedded capacitor having a case in which a condenser element and a coil part are incorporated, wherein an element set groove part in which the condenser element is embedded and a coil set-in groove part in which the coil part are provided are respectively provided in the case. The air vent penetrates the front, rear, and bottom of the case so that air flows between the element set groove and the coil set groove.

Description

Coil Built-in Capacitor

The present invention relates to a coil-embedded condenser, and more particularly, by separating the coil part and the condenser element embedded in the case from each other to form an air vent so as to be in another space, the heat generated from the coil part is air vented. The present invention relates to a coil-embedded capacitor in which air is cooled by air so as not to affect the capacitor element.

In general, a capacitor has a capacitance between two electrodes facing each other to have a capacitance, and when a voltage is applied between two electrodes facing each other with a dielectric (insulator) in between, the charge accumulates.

Capacitors having this function are classified into paper capacitors, film capacitors, and ceramic capacitors according to the type of dielectric, and although there are differences depending on the load applied to them, physical and chemical durability is weakened over time. Is inevitable.

Factors that greatly shorten capacitor life are affected by overvoltage, overcurrent and high ambient temperatures, which are known to be the most harmful load conditions for capacitors.

In particular, film capacitors are more susceptible to temperature because the dielectric material is a plastic film that is weak to heat. In fact, when the ambient temperature of the film capacitor rises by more than 7 ~ 8 ℃, the life is greatly halved. In addition, the film capacitor injects a sprayed metal such as zinc to both end surfaces of the capacitor element on which the film is wound, and solders the lead electrode to the electrode to withdraw the electrode from the deposited film.

Therefore, in the film capacitor, heat generation due to contact resistance is inevitably generated between the deposition metal and the thermal spray metal. Therefore, in the condenser element itself, both sides of the thermal condenser element with the thermal spray metal receive thermal energy due to the heat generation. Become.

Despite the weakness caused by such heat, the conventional film capacitor in which the coil is embedded has a structure in which heat is further transferred to the side of the capacitor element, which is weak to heat. In other words, the capacitor element is manufactured in a long cylindrical shape due to its characteristics. Therefore, in order to embed the capacitor element and the coil together in one case, it is preferable to arrange the coil to be located on one side of the capacitor element, and to make it embedded as such.

Therefore, in the coil built-in condenser of the prior art, it has no choice but to have a structure in which one side of the condenser element is adjacent to the coil, so that the thermal energy generated from the coil having a large amount of heat is directly vulnerable to heat. As a result, the deterioration of the plastic film element, which is a dielectric, is further promoted. In addition, the deterioration promotion of the plastic film element is the biggest cause of failure of the condenser element, and consequently becomes a problem of shortening the life of the capacitor.

In view of the conventional problems, the inventors of the Korean Utility Model Registration Application No. 98-5651 apply a coil-embedded condenser in which the thermal spray metal, which is the side that is the weakest part of the heat in the condenser element, is not affected by the heat energy generated in the coil. It is being elected by arc.

The present invention relates to an improvement of a capacitor pre- filed by the present applicant, an object of the present invention is to separate the coil unit and the condenser element embedded in the case to be in a different space and to form an air vent therebetween, An object of the present invention is to provide a coil-embedded capacitor in which heat generated in part is air-cooled by an air vent to prevent heat from being transferred to the capacitor element.

1 is an exploded perspective view of a condenser of an embodiment of the present invention.

2 is a cross-sectional view showing a state of charge of the capacitor of the embodiment of the present invention.

3 is a cross-sectional view showing a filled state of the condenser of the embodiment of the present invention.

Figure 4 is an exploded perspective view of another embodiment of the present invention.

Figure 5 is a cross-sectional view showing a filled state of another embodiment of the present invention.

6 is a sectional view taken along the line A-A of FIG.

* Explanation of symbols for main parts of the drawings

10 case 11 element set groove

12: coil set groove 13: air vent

15: reinforcing wall 20: condenser element

30 coil part

In order to achieve the above object, the present invention provides a coil-embedded capacitor having a case in which a capacitor element and a coil part are embedded, and an element set groove part in which the condenser element is embedded and a coil set-in groove part in which the coil part are built are respectively provided in the case. The air vent penetrates the front, rear, and bottom of the case so that air flows between the element set groove and the coil set groove.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view of a coil built-in condenser of the present invention, which is largely divided into a condenser element 20, a coil part 30, and a case 10 in which a condenser element and a coil part are built.

The condenser element 20 is manufactured in a long cylindrical shape to form the element circumferential surface portion 21 and the thermal spray metal surface portion 22 forming both sides thereof, and the thermal spray metal surface portion 22 on one side is exposed to the outside of the case 10. The electrode terminal 24 provided so that it may be provided is provided.

The electrode terminal 24 may be soldered by the lead wire 25 as shown in the drawing, or may be soldered directly to the sprayed metal surface 22. In the center of the condenser element 20, a core 23 for winding a film is provided.

The coil part 30 has a structure in which the winding coil 32 is wound so as to be aligned with the bobbin 31, and one end of the winding coil 31 is connected to the condenser element 20 and the other end thereof is drawn out to the outside. It is to be soldered to 33.

The case 10 includes an element settling groove 11 in which the condenser element 20 is embedded, and a coil settling groove 12 in which the coil unit 30 is embedded, respectively, and these settling grooves 11 and 12 are air. It is separated by the vent 13. The air vent 13 maintains a constant width to allow air to flow and maintains an interval such that heat generated from the coil portion 30 placed in the coil set groove portion 12 is not transferred to the element set groove portion 11. Keeping up.

2 and 3, the capacitor element 20 is fitted into the element set groove 11 of the case 10 and the coil portion 30 is fitted into the coil set groove 12. In this case, the electrode terminals 24 and 33 are installed to be exposed to the outside. In addition, one coil-embedded capacitor is completed by filling the filler 14 such as epoxy resin to solidify toward each settling portion 11 and 12 of the case 10.

According to the present invention configured as described above, the case 10 is divided into two spaces by the air vent 13, and the condenser element 20 and the coil part 30 are separately accommodated in these two spaces. Therefore, when the filler 14 is filled in these spaces, these capacitor elements and coil parts are built in a state in which they are separated from each other to complete the capacitor.

When the condenser of the present invention is operated, operating heat is generated at the coil part 30 side. The heat generated at this time is spread to all sides of the case and the heat radiated toward the air vent 13 is air cooled. Therefore, deterioration of the device is prevented because heat generated in the coil part is not transferred to the condenser device 20.

Figure 4 is an exploded perspective view of another embodiment of the present invention, Figure 5 is a cross-sectional view showing a filling state of another embodiment of the present invention, the same components as the embodiment of the present invention using the same reference numerals describe another embodiment of the present invention. .

Another embodiment of the present invention is a structure for reinforcing both side surfaces of the air vent 13 formed on one side of the case (10). A part of the case 10 is formed by the air vent 13 to be constricted, and when bending stress is concentrated in the part, there is a risk of bending and breaking. Therefore, both sides of the air vent 13 is blocked by the reinforcing wall 15 so as to have resistance to bending stress. Therefore, the air vent 13 is passed through the air toward the lower portion of the case 10, the air is less cool. However, the reliability of the product is improved by strengthening the bending stress.

As described above, according to the present invention, the condenser element and the coil part embedded in the case are located in different spaces, and an air vent is formed therebetween, so that heat generated from the coil part is air-cooled by the air vent. Therefore, the capacitor element is prevented from being deteriorated, thereby increasing the lifespan and improving the reliability of the product.

In addition, since the capacitor element is not subjected to heat, the voltage per unit thickness of the dielectric film can be improved, and consequently contributes to cost reduction.

Claims (2)

A coil-embedded capacitor having a case in which a condenser element and a coil part are embedded, wherein the element set groove part in which the condenser element is embedded and the coil set groove part in which the coil part are built are respectively provided in the case, and the element set groove part and the coil are provided. The coil-mounted condenser characterized in that the air vent penetrating the front, rear and lower portion of the case so that air flows between the settled groove portion. The coil-integrated capacitor according to claim 1, wherein a reinforcing wall which blocks the front and rear of the air vent is formed in the case so that the bending stress of the case is reinforced.