KR100978803B1 - Feeder belt for strip-shaped elements - Google Patents

Abstract

The present invention relates to a conveyance belt utilized for the purpose of conveying strip-shaped components in various processing processes, such as a plating process for manufacturing a component such as a semiconductor, in particular, even when the non-conductive encapsulation is held by the finger of the belt. It relates to a conveying belt for strip-shaped parts that enables separate electrical connection.

According to the present invention, in the process of manufacturing a large amount of semiconductor or other components, the processing process such as plating process in the automated in-line process by coupling the fingers to the belt body at a predetermined pitch interval for transfer in the state holding the strip-shaped parts In the belt for conveying strip-shaped components utilized as a plurality of conductive connections provided at a predetermined pitch interval on one side of the belt body, the conductive connection portion is formed extending from the belt body, when viewed from the side It is characterized in that it provides a belt for transporting a strip-shaped part in which an upper first bent portion bent in one direction and a lower second bent portion bent in a direction opposite to the first bent portion are respectively extended.

Semiconductor, component, plating process, processing process, strip form, transfer belt, finger, non-conductive encapsulation, electrical connection

Description

Feeder belt for strip-shaped elements

The present invention relates to a conveyance belt utilized for the purpose of conveying strip-shaped components in various processing processes, such as a plating process for manufacturing a component such as a semiconductor, in particular, even when the non-conductive encapsulation is held by the finger of the belt. It relates to a conveying belt for strip-shaped parts that enables separate electrical connection.

In general, in the case of a belt for conveying strip-shaped parts, US Pat. No. 4,534,843 is known as a type in which the belt body and the finger are integrally formed, and the type in which the belt body and the finger are separated and coupled is US Patent No. 5,024,745 or the applicant's US Patents 7,128,817 and US Pat. No. 7,303,064 are known.

In addition, the conventional prior art is applied to a lead frame strip-shaped part having a conventional shape in a plating process for manufacturing an electronic part such as a semiconductor, as illustrated in FIG. 1, the belt body 1 and the finger 3. The conductive lead frame portion 5b, not the encapsulation portion 5a, is gripped between the lead frame strip-shaped parts 5 so that the belt body 1 and the lead frame portion 5b are naturally electrically energized or connected. This is preferably used in the plating process.

However, as shown in FIGS. 1 and 2, the shape of the recent leadframe strip-shaped part 5, which constitutes an electronic component such as a semiconductor, is encapsulated at both ends in order to reduce materials and reduce production cost while improving productivity. Forming portions 5a and 5a and forming lead frame portions 5b between these encapsulation portions 5a and 5a, respectively, which lead frame portions 5b are actually utilized effective lead frame portions 5c. The design is changed and used to have a cutting margin (5d) to be used only in the processing process and cut after completion.

When the conventional belt is applied to the leadframe strip-shaped part 5 illustrated in FIGS. 2 and 3, the strip form is formed between the belt body 1 and the finger 3 as illustrated in FIG. The belt body 1 and the strip-shaped part 5 are electrically energized or connected to each other due to the characteristics of the non-conductive encapsulation portion 5a, which is inevitably gripped with the encapsulation portion 5a of the component 5 positioned. Since this cannot be done, there is a problem in that the plating process cannot be performed.

In addition, there is no countermeasure for the existing conveying belt, so the lead frame strip-shaped part 5 having the shapes illustrated in FIGS. 2 and 3 cannot be applied to the automated processing process by the existing belt feeding method. In the semiconductor manufacturing process in this regard, the plating operation is inevitably caused by the fact that it has to rely almost on manual work.

The present invention has been made in order to solve such a conventional problem has the following object.

The main object of the present invention is to extend from the belt main body to the conductive lead frame part when the portion of the lead frame strip-shaped part for semiconductor manufacturing located in the grip portion between the belt body and the finger is non-conductive, for example, when the encapsulation portion is located. The purpose of the present invention is to provide a separate conduction connection part so that the gripping part may be used for transferring lead frame strip-shaped parts even when the conductive part is non-conductive.

Another object of the present invention is to simplify the structure in the case of the energized connecting portion applied in the present invention to provide an easy transport belt for strip-shaped parts, which is easy to manufacture and does not affect the productivity of the belt.

In order to achieve the above objects, the present invention provides a strip-shaped component by coupling fingers to a belt body at predetermined pitch intervals in an automated in-line process such as a plating process during a process of manufacturing a large amount of semiconductor or other components. In the belt for conveying strip-shaped parts utilized for conveying in a gripped state, a plurality of energizing connecting portions are separately provided at a predetermined pitch interval on one side of the belt main body, and the energizing connecting portions are formed to extend from the belt main body. However, when viewed from the side, the belt for transporting the strip-shaped part formed by extending the first bent portion of the upper portion bent in one direction and the second bent portion of the lower portion bent in the opposite direction to the first bent portion to provide.

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In addition, the energized connecting portion is formed extending from the belt body, the front view of the strip-shaped component is formed by the wide portion formed in a wider upper portion and the narrow portion formed in a narrower width than the wide portion formed in the lower portion Provide a transfer belt.

Further, the energizing connecting portion is provided in the lower portion of the belt body at a predetermined pitch interval, the strip-shaped component is formed so that the second bent portion formed in each of the energizing connecting portion makes contact with the cutting margin of the strip-shaped component To provide a conveying belt.

According to the present invention, when a plurality of conduction connecting portions are provided on one side of the belt body at regular pitch intervals and the portion of the lead frame strip-shaped part for semiconductor manufacturing located at the grip portion between the belt body and the finger is non-conductive, it is conductive from the belt body. It can be used for the transfer of lead frame strip-shaped parts by providing a separate energized connection part up to the lead frame part of the device. In the case of the energized connection part, the structure is simplified and is easy to manufacture and greatly affects the productivity of the belt. It can be used more effectively.

Hereinafter, with reference to the accompanying drawings Figures 5 to 12 will be described in more detail with reference to a specific embodiment of the present invention.

Various embodiments illustrated in FIGS. 5 to 12 are common in which a process such as a plating process is performed at a predetermined pitch interval in a belt body 1 in an automated in-line process during a process of manufacturing a large amount of semiconductors or other components. In the transfer belt of the strip-shaped part (5) to be used for the transfer in the state of holding the strip-shaped component (5) by coupling (3), at a predetermined pitch interval on one side of the belt body (1) It is made by separately providing a plurality of energization connecting portion (7).

At this time, the energized connecting portion 7 is formed extending from the belt body 1, and the first bent portion 70 and the first bent portion 70 of the upper bent in one direction when viewed from the side The lower second bent portions 72 which are bent in the opposite direction are each formed to have a connecting force by elastic support so that a smooth electrical connection can be made with the strip-shaped part 5.

In addition, the energization connecting portion 7 is formed to extend from the belt main body, the wide portion 74 formed in a wider upper portion when viewed from the front and the narrow portion 76 formed in a narrower width than the wide portion in the lower portion ) Is formed so that the electrical connection is made enough while saving the material is made.

Furthermore, the conductive connecting portion 7 is provided in the lower portion of the belt body 1 at a predetermined pitch interval, the second bent portion 72 formed in each of the conductive connecting portion 7 is strip-shaped parts It is preferable to comprise so that the contact with the cutting margin part 5d of (5) may be made.

Of course, in the above-described embodiment, the energization connecting portion 7 is shown centering on the embodiment configured integrally with the belt body 1, but the energization connecting portion 7 is manufactured separately to the belt body 1 It is also possible to install and use in combination, and the energized connection portion 7 can be configured in various forms as illustrated in FIGS. 5 to 10 or 11 and 12.

The present invention made as described above is made as follows.

In use, as illustrated in FIGS. 9 and 10 or 11 and 12, the strip-shaped part 5 is gripped between the belt main body 1 and the finger 3 to feed the belt main body. The non-conductive encapsulation portion 5a is positioned at the strip-shaped part 5 at a position between the finger 1 and the finger 3, but the separately provided conduction connecting portion 7 is conductive at the strip-shaped part 5. The electrical connection with the lead frame portion 5b of the lead frame portion 5b is performed, and the plating operation of the lead frame portion 5b is performed even during the continuous feeding of the strip-shaped part 5 by the belt body 1 and the finger 3. It can be made smoothly.

In particular, the energization connecting portion 7 is formed by bending the first bent portion 70 and the second bent portion 72 in different directions, and the wide portion 74 and the narrow portion 76 are connected, The strip-shaped part by the belt main body 1 and the finger 3 while the second bent portion 72 maintains elastic and electrical contact with the cutting free portion 5d of the lead frame portion 5b. In the process of continuous feeding with the gripping of (5), the cutting free portion 5d which is not actually utilized in the lead frame portion 5b is used as a contact point by the energization connecting portion 7 and the cutting free portion ( As a portion other than 5d), the plating operation of the effective lead frame portion 5c which is actually used as a lead frame can be performed smoothly.

Therefore, according to the present invention, a plurality of energization connecting portions 7 are provided on one side of the belt main body 1 at regular pitch intervals, and the belt main body 1 and the fingers ( 3) In the case where the portion located between the holding portions is non-conductive, a separate conducting connecting portion 7 which can be electrically connected from the belt main body 1 to the conductive lead frame portion 5b is provided and leads It can be used for the transfer of the frame strip-shaped part 5, and in the case of the energized connection part 7, the structure is simplified to facilitate the manufacture and does not significantly affect the productivity of the belt. Can be.

1 is a side view illustrating a form in which a conventional lead frame strip shaped part is gripped with a conventional belt;

Figure 2 is a front view showing a preferred example of the lead frame strip-shaped component that is recently applied,

3 is a side view of FIG.

4 is a side view illustrating a form in which the lead frame strip shaped parts illustrated in FIGS. 2 and 3 are gripped with a conventional belt;

5 is a front view showing a preferred example of the present inventors belt,

6 is an enlarged view illustrating main parts of FIG. 5;

7 is a side view of FIG. 5;

8 is an enlarged view illustrating main parts of FIG. 7;

9 is a front view illustrating a form in which the lead frame strip shaped parts illustrated in FIGS. 2 and 3 are gripped by a belt of the present invention illustrated in FIGS. 5 to 8;

10 is a side view of FIG. 9;

11 is a front view showing another example of the belt of the present invention corresponding to FIG. 9;

12 is a side view of FIG. 11;

<Explanation of symbols for the main parts of the drawings>

1: belt body, 3: finger,

5: strip-shaped part, 5a: encapsulation part,

5b: leadframe section, 5c: effective leadframe section,

5d: cutting margin, 7: energized connection,

70: first bend, 72: second bend,

74: wide part, 76: narrow part

Claims (4)

In the process of manufacturing a large amount of semiconductors and other parts, in the automated in-line process, the process of plating and stripping is carried out by holding fingers in the belt body at fixed pitch intervals. In the belt for conveying parts, On one side of the belt body is provided with a plurality of conduction connection separately at a constant pitch interval, the conduction connection is formed extending from the belt body, As viewed from the side, the first bent portion bent in one direction and the second bent portion bent in the opposite direction to the first bent portion for the transfer of the strip-shaped component, characterized in that formed respectively belt. delete The method of claim 1, The energizing connection is formed extending from the belt body, A belt for transporting a strip-shaped part, characterized in that a wider portion having a wider width at the top and a narrower portion having a narrower width than the wider portion are formed at the front side. The method of claim 1, The conductive connection portion is provided on the lower portion of the belt body at a predetermined pitch interval, And said second bent portion formed in each of said energized connection portions makes contact with the cutting margin of said strip shaped part.

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