RU2013816C1 - Process of manufacture of oxide-semiconductor chip capacitors - Google Patents

Abstract

FIELD: electronics. SUBSTANCE: sections K with wire leads are soldered to output frame composed of cathode flat lead and flat outer anode lead. End of flat outer anode lead is divided into three parts. Cathode lead of section is soldered to flat cathode lead and wire anode lead is welded to center part of flat outer anode lead. Safety element from fusible metal is set between center part of flat outer anode lead and extreme part. EFFECT: simplified design and miniaturization of structure. 5 dwg

Description

 The invention relates to electronics and can be used in the manufacture of lead-free oxide semiconductor capacitors.

 The manufacturing process of such capacitors includes the formation of a section with a wire terminal embedded in the body of the anode, followed by its connection with the external terminal and packaging. When a capacitor is included in electrical circuits in the event of a voltage exceeding the nominal voltage in the circuit, it is destroyed, leading to a short circuit, and other components of the circuit can be destroyed.

 The purpose of the invention is the creation of a small capacitor having a reliable protective device.

 Known fuse for solid-state electrolytic capacitor [1], containing a fuse in the form of a plate of a composite metal alloy coated with refractory silicon and an insulating plate. One end of the plate is connected to the anode terminal of the capacitor, and the second to a flat outer terminal.

 The disadvantage of this method is to increase the dimensions of the capacitor by the length of the safety element and the complex technology for producing the safety element.

 A known method of manufacturing solid electrolytic capacitors in the form of a CHIP according to the Japanese patent taken as a prototype, in which the anode terminals of the capacitor sections are connected to the output frame (with the outer anode flat terminal) through a safety element located along the axis of the anode terminal made of a flat anode outer terminal material .

 The disadvantage of this method is to increase the dimensions of the capacitor, since the sealed part of the capacitor increases by the size of the safety element.

 According to this method, it is impossible to obtain a safety element with low protection currents due to the technological capabilities of stamping and the need to have a flat anode terminal material of a certain thickness.

 In addition, the lead frame loses its rigidity, since the main part of it is held on by the safety elements, which can lead to the breakage of the safety elements during the manufacture of capacitors.

 To eliminate these shortcomings in the proposed technical solution, the end part of the flat external anode terminal is divided into three parts before packing, the anode terminal is connected to the middle part and through the safety element from one of the extreme parts, which allows the safety element to be included in the capacitor design without increasing the length of the flat terminal , and therefore, reduce the size of the capacitors.

 The safety element is made of fusible material that burns out when an excessively large current flows.

 The casing is carried out so that a part of the divided flat external anode terminal protrudes beyond the housing so that the middle part can be removed, which ensures that the flat external anode terminal is connected to the wire anode terminal through a safety element without increasing the length of the flat external anode terminal, and therefore , reduces the dimensions of the capacitor. To increase the reliability of the CHIP capacitors, the wire anode terminal is connected through safety elements to both extreme parts of the flat external anode terminal.

 A significant difference of the proposed method is that in the process of patent search did not reveal a technical solution with a similar set of features that has the same properties that provide the achieved positive effect.

 In FIG. 1 shows a General view of the technological output frame with sections of capacitors; in FIG. 2 - the same side view; in FIG. 3 - output frame after sealing with a compound, top view; in FIG. 4 - an output frame sealed with a compound, after disconnecting the middle part of the flat anode terminal, top view; in FIG. 5 is a sectional perspective view of a capacitor.

 Section 1 of the CHIP capacitor is obtained by sintering a billet of powder of a valve metal, for example aluminum, followed by molding to obtain an oxide film, applying a semiconductor layer, a carbon layer and a metal layer for soldering the external output.

 Section 1 of the capacitors with wire leads 2 is soldered to the lead frame 3, consisting of a cathode flat lead 4 and a flat outer anode lead 5. The end part, about 1/3 of the length of the flat outer anode lead 5, is divided into 3 parts when stamped: middle part 6 and the extreme parts 7 and 8. Moreover, the cathode terminal of section 1 is soldered to the flat cathode terminal 4, and the wire anode terminal 2 is welded to the middle part 6 of the flat external anode terminal 5. Between the middle part 6 of the flat external anode terminal 5 and the extreme part 7 by welding, a safety element 9 of aluminum wire is installed.

 For special highly reliable chip capacitors between the middle part 6 of the flat outer terminal 5 and the extreme part 8, a backup safety element 10 made of aluminum wire is installed by welding.

 After attaching the section 1 to the output frame 3, the section 1 is sealed with compound 11 in the molds. After sealing, the middle part 6 of the flat anode terminal 5, protruding beyond the body, cut down. The flat leads 5 and 4 are cut off from the lead frame 3 and bent U-shaped.

 This method of manufacturing chip-capacitors allows you to get a safety element with a low current protection, as it is made of fusible material, while maintaining the rigidity of the output frame and reducing the dimensions of the capacitor.

 Additionally, the bending of the terminal is facilitated, since only the extreme parts 7 and 8 of the flat external anode terminal are subjected to deformation. To increase the reliability of the capacitor, it is possible to connect the middle part of the flat anode external output through the safety elements with both extreme parts 7 and 8. In the event of a defective element being defective, the performance of the capacitor is ensured by the second safety element.

Claims (1)

 METHOD FOR PRODUCING OXIDE SEMICONDUCTOR CHIP CAPACITORS, comprising connecting the wire anode terminal of the capacitor section with the external flat anode terminal of the capacitor through the safety element and the cathode terminal of the section with the external cathode terminal of the capacitor, sealing the section with a compound, cutting off the outer terminals of the capacitor that before connecting the anode terminal of the section with the anode terminal of the capacitor, the end part of the flat anode terminal of the capacitor is divided into three hours The wire anode terminal of the section is connected to the middle part of the flat external terminal of the capacitor, and the safety element is placed between the middle part of the external anode terminal of the capacitor and one of its extreme parts, or two safety elements are placed between the middle part of the external anode terminal of the capacitor and each of its extreme parts, when sealing the section, the separated parts of the anode output of the capacitor are left free, and after sealing the middle part is removed.

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