JPH0243718A - Exterior coating process of capacitor - Google Patents

Abstract

PURPOSE:To miniaturize chip film capacitors for enabling them to be manufactured at a low cost by a method wherein laminated layer type capacitor elements are arranged on a UV curing resin coated on a holder with their cut off surfaces brought into contact with the resin. CONSTITUTION:A holder 1 is coated with the UV curing resin 2 as an exterior member and them laminated layer type film capacitor element 3 are arranged on said UV curing resin 2 with their cut off surfaces 4, 7 brought into contact with the resin 2. Next, said UV curing resin 2 set by UV irradiation is released from the interface with the holder 1 to form the laminated layer type film capacitor element 3 with the UV resin coating 6. For example, the UV curing resin 2 is formed on the UV transmissible film sheet 1 and then the capacitor elements 3 are fixed to the resin film 2 with their side cut off surface 4 brought into contact with the resin film 2 which is irradiated with UV ray by a UV ray lamp 5 to cure the resin film 2. Finally, the other side cut off surface 7 is processed likewise.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a method of packaging capacitors, particularly multilayer capacitors.

BACKGROUND OF THE INVENTION In recent years, as electronic devices and electrical devices have become smaller, thinner, and more densely packed, electronic components have been increasingly made into chips and surface-mounted.

Ceramic capacitors and solid electrolytic capacitors have been widely used as chip capacitors.

On the other hand, in the field of film capacitors, a chip-shaped multilayer film capacitor with good heat resistance has been developed that uses polyphenylene sulfide film as a dielectric, and it has become possible to withstand soldering temperatures well. Chip-shaped film capacitors are also rapidly becoming popular, partly because they have superior electrical characteristics and reliability compared to ceramic capacitors and electrolytic capacitors.

FIG. 4 is a process perspective view for explaining a conventional method for packaging a chip film capacitor by transfer molding.

In this method, as shown in the figure, after welding the external electrodes 43 and 44 of the chip film capacitor element 42 to the comb lead 41 to form a multi-connected structure, The chip film capacitor elements 42 are respectively arranged in 47 (the element housing portion on the upper mold 45 side is not shown in the figure), and both molds 45 and 46 are brought together.

Next, the powdered epoxy resin 49 is placed in the hopper 48.
is transferred to the bod 50 and melted, and then a pressure of 60 to 90 kg/cd is applied with the plunger 51 to fill the Evokin resin 49 into the element housing portion 47 and harden it.

Chip film capacitor 5 packaged in this way
2 is obtained.

The resin used for the body 50 and both molds 45 and 46 was 150~
It is melted and hardened by heating to about 180°C.

FIG. 5 is a partially cutaway perspective view of a chip film capacitor 52 manufactured as described above.

The chip film capacitor element 42 is Comlead's 41
(the electrode connected to the other electrode 43 is not shown), and is covered with an exterior body 54 made of Evokin resin.

The characteristics of the products obtained by this transfer molding are that the external dimensions have high precision and small variations.

This is because the external dimensions of the product are determined by the dimensions of the element housing portion of the mold.

Problems to be Solved by the Invention However, according to this conventional method, the thickness of the exterior body 54 shown in FIG. 54, the ratio of the thickness of the exterior body 54 to the product dimensions becomes large, which is a factor that hinders miniaturization.

In addition, in terms of manufacturing costs, the manufacturing equipment is expensive,
Running costs, including electricity rates, are also becoming more expensive.

In this way, it is extremely difficult to miniaturize chip film capacitors using the method of forming the outer body through transfer molding, which results in a larger shape than other capacitors such as ceramic capacitors, and the manufacturing cost is high. Therefore, the reality is that the unit price has to be higher than other capacitors.

The present invention aims to provide a method that allows chip film capacitors to be made smaller than conventional products and manufactured at low cost.

Means for Solving the Problems A first method for packaging a capacitor according to the present invention is to place a laminated film capacitor element with its cut surface in contact with an ultraviolet curing resin coated on a support, and to apply an ultraviolet curing resin. This method involves curing the resin and then peeling off the cured ultraviolet curable resin film from the support to form a multilayer film capacitor element having an ultraviolet curable resin exterior body on the cut surface.

In the second packaging method of the present invention, a roller having a predetermined thickness of liquid packaging material is brought into contact with a cut surface of a laminated film container element to transfer the liquid packaging material onto the cut surface. This is a method in which a liquid resin material adhered to the cut surface of a laminated film capacitor element is cured to form an exterior body.

Function: In the packaging method of the present invention, the packaging is formed by transferring the packaging on the cut surface of the multilayer film capacitor element. Therefore, the thickness of the exterior body is 0.001~
It is now possible to form an extremely thin layer of 0.15 mm.
The product external dimensions are almost the same as the element dimensions.

EXAMPLES Hereinafter, examples of the method of the present invention will be described with reference to the drawings.

[Example 1] FIG. 1 is a perspective view showing an example of a step of packaging a cut surface of a chip film capacitor element with an ultraviolet curing resin.

Continuous UV-transparent film sheet 1 as support
The ultraviolet curable resin film 2 is formed by applying ultraviolet curable resin to a predetermined thickness using a rubber roller or the like. Then, the film capacitor element 3 is mounted on the film sheet 1 so that one of its cut surfaces 4 is in contact with the ultraviolet curing resin film 2, and ultraviolet rays are applied to the film sheet 1 from the side opposite to the side on which the element 3 is attached using an ultraviolet lamp 5. The ultraviolet curing resin film 2 is cured by irradiation.

Then, the film capacitor element 3 is removed from the film sheet 1 by peeling it off at the interface between the film sheet 1 and the ultraviolet curing resin film 2. As a result, an exterior body 6 made of ultraviolet curing resin is formed on one cut surface 4 of the film capacitor element 3. Then, the other cut surface 7 is also provided with an exterior body in the same manner.

Note that the film sheet 1 may be one that transmits 1% or more of ultraviolet rays, and may have a long shape.

Furthermore, a thin plate-shaped body that is transparent to ultraviolet rays may be used in place of the film sheet.

[Example 2] FIG. 2 is a perspective view showing an example of the process of forming an exterior body made of Epoquine resin on a cut surface of a chip film capacitor element.

A liquid Epoquine resin 9 is applied to the rubber roller 8 as an exterior member.
is stretched and adhered to a predetermined thickness, and brought into contact with one cut surface of the film capacitor element 3. As a result, the liquid Epoquin resin 9 is transferred to the cut surface 4 of the film capacitor element 3, and a liquid Epoquin resin layer 10 is formed. Then, the liquid Evokin resin 9 is similarly transferred to the other cut surface 7 to form a resin layer. Then, by curing the liquid epoxy resin transferred to the cut surfaces 4 , 7 of the film capacitor element 3 , an exterior body made of epoxy resin is formed on the cut surfaces 4 , 7 of the film capacitor element 3 .

FIG. 3 shows the structure of the chip film capacitor 31 according to the above-described embodiment 1.2.

In this film capacitor 11, a thin outer body 6.12 is applied to each cut surface 4.7 of the film capacitor element 3. In addition, 13.14 is film capacitor 1
1 external electrode.

The thickness of the exterior body 6.12 [1 is 0.001 mm to 0.001 mm].
15mm, and its shape is 20% smaller in volume compared to products obtained by conventional transfer molding.
The size is significantly reduced by ~60%. This means that the method of the present invention will be very effective if film capacitor elements are to be further miniaturized in the future.

The equipment for carrying out the process is much simpler and smaller than a ton transfer molding machine, and less material is required to form the exterior body, so running costs are reduced and inexpensive chip film can be used. Capacitors can be obtained.

Effects of the Invention According to the method of the present invention, film capacitors can be significantly downsized, and the equipment for carrying out the process is much simpler than in the case of the transfer method, and production running costs are also reduced. It is inexpensive and can improve mass productivity.

[Brief explanation of the drawing]

FIGS. 1 and 2 are perspective views showing the main steps of an example of the method for packaging a film capacitor according to the present invention, and FIG. 3 is a partially cutaway perspective view of a film capacitor obtained by these examples. be. FIG. 4 is a process perspective view showing a conventional method for packaging a film capacitor, and FIG. 5 is a partially cutaway perspective view of a film capacitor obtained by this conventional method. 1... Film sheet, 2... Ultraviolet curing resin, 3... Film capacitor element, 4
, 7...Cut surface, 5...Ultraviolet lamp, 6...Exterior body, 8...Rubber roller 9...Liquid epoxy resin , 10...Liquid epoxy resin layer, 11...Film capacitor, 12...Exterior body, 13.14...
external electrode. Name of agent: Patent attorney Shigetaka Awano (1 person)

Claims (2)

[Claims] (1) a step of applying an ultraviolet curable resin as an exterior member onto a support; a step of arranging a laminated film capacitor element on the coating film of the ultraviolet curable resin with its cut surface in contact; curing the ultraviolet curable resin by ultraviolet irradiation, and then peeling off the ultraviolet curable resin at the interface with the support to form a multilayer film capacitor element having an ultraviolet curable resin exterior body on the cut surface; A method for packaging a capacitor, comprising: (2) Transferring the liquid resin material to the cut surface of the multilayer film capacitor element by bringing a roller to which the liquid exterior material is adhered to a predetermined thickness into contact with the cut surface of the multilayer film capacitor element; A method for packaging a capacitor, comprising the steps of: curing the liquid resin material adhering to the cut surface of the laminated film capacitor element to form an exterior body.