JP2021061303A - Flexible printed wiring board array, manufacturing method thereof, and flexible printed wiring board - Google Patents

Abstract

To provide a flexible printed wiring board array, a manufacturing method thereof, and a flexible printed wiring board having excellent handleability.SOLUTION: In a flexible printed wiring board array according to an embodiment of the present invention in which a plurality of printed wiring board pieces are arranged, the printed wiring board piece includes a base film, a first conductive pattern laminated on the base film, and a second conductive pattern that is laminated in a region other than the laminated region of the first conductive pattern in the base film and is not electrically connected to the first conductive pattern.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to a flexible printed wiring board array, a method for manufacturing the same, and a flexible printed wiring board.

Flexible printed wiring boards are widely used to configure circuits of various electronic devices. In recent years, with the miniaturization of electronic devices, the miniaturization of flexible printed wiring boards and the increase in the wiring density thereof have been remarkable.

Such a small flexible printed wiring board is generally formed by arranging a desired conductive pattern of the small flexible printed wiring board to be finally obtained on the surface of a large-sized sheet-like insulating base material. Create a flexible printed wiring board array. By cutting out each flexible printed wiring board from this flexible printed wiring board array, flexible printed wiring boards are mass-produced (Japanese Unexamined Patent Publication No. 2018-67694).

JP-A-2018-67694

In the flexible printed wiring board array, a plurality of individual pieces including each of the flexible printed wiring boards are arranged corresponding to each flexible printed wiring board. In this flexible printed wiring board array, a coating layer forming sheet is usually superposed on a base film with a conductive pattern sandwiched between them, and heated to form a coating layer (also called a coverlay). The conductive pattern is coated with this coating layer.

When heated in this way, problems such as bending of the flexible printed wiring board array may occur. When this bending occurs, the handleability of the flexible printed wiring board array deteriorates. As a result, the cut out flexible printed wiring board may also be bent, and its handleability may be deteriorated.

Therefore, it is an object of the present invention to provide a flexible printed wiring board array having excellent handleability, a manufacturing method thereof, and a flexible printed wiring board.

The flexible printed wiring board array according to one aspect of the present disclosure made to solve the above problems is a flexible printed wiring board array in which a plurality of printed wiring board pieces are arranged, and the printed wiring board pieces are arranged. Is laminated in a region other than the base film, the first conductive pattern laminated on the base film, and the laminated region of the first conductive pattern in the base film, and is electrically connected to the first conductive pattern. It is provided with a second conductive pattern that is not provided.

Further, the method for manufacturing a flexible printed wiring board array according to another aspect of the present disclosure, which has been made to solve the above problems, is a method for manufacturing a flexible printed wiring board array in which a plurality of printed wiring board pieces are arranged. Therefore, a step of laminating a first conductive pattern and a second conductive pattern that is not electrically connected to the first conductive pattern is provided on the base film, and in the laminating step, the first conductive pattern of the base film is laminated. The second conductive pattern is laminated in a region other than the laminated region.

Further, the flexible printed wiring board according to another aspect of the present disclosure made to solve the above problems includes a base film, a first conductive pattern laminated on the base film, and the first conductive pattern in the base film. It includes a second conductive pattern that is laminated in a region other than the laminated region of the conductive pattern and is not electrically connected to the first conductive pattern.

A flexible printed wiring board array according to one aspect of the present disclosure, a flexible printed wiring board array obtained by a method for manufacturing a flexible printed wiring board according to another aspect of the present disclosure, and a flexible printed wiring board according to another aspect of the present disclosure. Is excellent in handleability.

FIG. 1 is a schematic plan view showing a flexible printed wiring board array of the first embodiment. FIG. 2 is a schematic partially enlarged plan view showing a printed wiring board piece at one corner and its periphery in the flexible printed wiring board array of FIG. FIG. 3 is an end view taken along the line AA of FIG. FIG. 4 is a schematic partially enlarged end view of a printed wiring board piece cut along a reference straight line. FIG. 5 is a schematic partially enlarged plan view showing a printed wiring board piece at one corner and its periphery in the flexible printed wiring board array of the second embodiment.

[Explanation of Embodiments of the present disclosure]
The flexible printed wiring board array according to one aspect of the present disclosure is a flexible printed wiring board array in which a plurality of printed wiring board pieces are arranged, and the printed wiring board pieces are a base film and the base film. The first conductive pattern laminated on the base film and a second conductive pattern laminated on a region other than the laminated region of the first conductive pattern on the base film and not electrically connected to the first conductive pattern. ..

Here, in the conventional flexible printed wiring board array described above, only the first conductive pattern is laminated on the base film. In this case, since the region of the base film on which the first conductive pattern is laminated is held by the first conductive pattern, it is difficult to bend even when heated. On the other hand, the region of the base film in which the first conductive pattern is not laminated is not held by the first conductive pattern, and therefore easily bends when heated. On the other hand, since the arrangement of the first conductive pattern on the base film is restricted by the request of the circuit design, it is difficult to freely change the arrangement. Therefore, in the above-mentioned conventional technique, it is difficult to arrange the first conductive pattern so that the base film does not bend.

In this regard, in the flexible printed wiring board array, each printed wiring board piece has a second conductive pattern in addition to the first conductive pattern. Therefore, in the flexible printed wiring board array, the first conductive pattern and the second conductive pattern are laminated at different positions on the base film in the entire array. In this way, by laminating the second conductive pattern on the region where the first conductive pattern is not laminated on the base film, the region where the second conductive pattern is laminated is held by the second conductive pattern. , It becomes difficult to bend even if it is heated as described above. Moreover, since the second conductive pattern is not electrically connected to the first conductive pattern, it is difficult to impair the function of the first conductive pattern. In addition, since it is difficult to impede the function of the first conductive pattern in this way, it is possible to design the second conductive pattern regardless of the first conductive pattern. That is, it is possible to increase the degree of freedom in design to make it difficult to bend. Therefore, since the printed wiring board pieces have the second conductive pattern in addition to the first conductive pattern, the portion of the base film that is easily bent is reduced, and the flexible printed wiring board array is said to have suppressed bending. Become. Therefore, the flexible printed wiring board array is excellent in handleability.

In the reference straight line passing through the center of the printed wiring board piece, the total length of the region intersecting at least one of the first conductive pattern and the second conductive pattern does not intersect with the first conductive pattern and the second conductive pattern. It should be larger than the total length of the area.

As described above, the total length of the region intersecting at least one of the first conductive pattern and the second conductive pattern in the reference straight line is larger than the total length of the region not intersecting the first conductive pattern and the second conductive pattern. It is possible to reduce the easily bendable area in the flexible printed wiring board array. Therefore, the bending of the flexible printed wiring board array is further suppressed. Therefore, the flexible printed wiring board array is more excellent in handleability.

The printed wiring board piece may have an outer edge region. Here, when the printed wiring board piece has an outer edge region and the printed wiring board piece has only the first conductive pattern, the portion of the base film that is easily bent increases by the amount of this outer edge region, and the printed wiring board piece bends. Is likely to occur. However, when the printed wiring board pieces have an outer edge region, since the printed wiring board pieces have a second conductive pattern in addition to the first conductive pattern, the flexible printed wiring board array has less bendable parts. .. Therefore, the flexible printed wiring board array has its bending suppressed. Therefore, when the printed wiring board pieces have an outer edge region, the effect of the flexible printed wiring board array becomes more remarkable.

The second conductive pattern may be a solid pattern or a grid pattern. As described above, when the second conductive pattern is a solid pattern or a grid pattern, the second conductive pattern can be easily laminated in a wider range in the region where the first conductive pattern is not laminated on the base film. Therefore, the bending of the flexible printed wiring board array is further suppressed. Therefore, the flexible printed wiring board array is more excellent in handleability.

A part of the first conductive pattern may form a coil portion. Here, since the coil portion usually has a curved shape in a plan view, a region where the first conductive patterns are not laminated between the first conductive patterns and in the first conductive pattern (inside the coil portion). Is relatively large. That is, the easily bendable portion of the base film tends to be relatively large. Therefore, when the printed wiring board piece has only the first conductive pattern, bending is likely to occur. However, even in such a case where the flexible printed wiring board array is easily bent, the bending of the flexible printed wiring board array is suppressed by laminating the second conductive pattern in the region where the first conductive pattern is not laminated. It becomes. Therefore, since a part of the first conductive pattern constitutes the coil portion, the effect of the flexible printed wiring board array becomes more remarkable.

It is preferable that the printed wiring board piece further includes a coating layer that covers the first conductive pattern and the second conductive pattern. Here, as described above, usually, the base film is easily bent because heating is involved in forming the coating layer. Therefore, when the printed wiring board piece has only the first pattern, bending is likely to occur. However, even when bending is likely to occur in this way, it is possible to suppress bending of the flexible printed wiring board array during heating by providing the second conductive pattern as described above. Therefore, the effect of the flexible printed wiring board array becomes more remarkable by providing the coating layer.

Further, the method for manufacturing a flexible printed wiring board array according to a different aspect of the present disclosure is a method for manufacturing a flexible printed wiring board array in which a plurality of printed wiring board pieces are arranged, and a first conductive pattern is formed on a base film. A step of laminating the first conductive pattern and the second conductive pattern that is not electrically connected is provided. In the laminating step, the second conductive pattern is placed in a region other than the laminated region of the first conductive pattern in the base film. Stack conductive patterns.

According to the method for manufacturing the flexible printed wiring board array, the above-mentioned flexible printed wiring board array can be manufactured. That is, it is possible to manufacture a flexible printed wiring board array having excellent handleability.

Further, the flexible printed wiring board according to a different aspect of the present disclosure is laminated in a region other than the base film, the first conductive pattern laminated on the base film, and the laminated region of the first conductive pattern in the base film. A second conductive pattern that is not electrically connected to the first conductive pattern is provided.

Similar to the flexible printed wiring board array described above, the flexible printed wiring board is provided with the second conductive pattern, so that the region in which neither the first conductive pattern nor the second conductive pattern is formed in the base film is reduced. Bending is suppressed. Therefore, the flexible printed wiring board is excellent in handleability.

Here, the "first conductive pattern" means a pattern that exerts a function as wiring when energized. The "second conductive pattern" means a pattern that is not energized and does not function as wiring.

The "printed wiring board individual piece" means a portion for partitioning a flexible printed wiring board array so as to include an area (hereinafter, may be referred to as a "wiring board area") that becomes a flexible printed wiring board by being cut out. .. This "printed wiring board piece" may have an outer edge region in addition to the wiring board region. The “outer edge region” means an region that surrounds all or part of the wiring board region.

The “first conductive pattern laminated region” means a region in which the wiring of the first conductive pattern is laminated. The "center of the printed wiring board piece" means the geometric center of the outer peripheral edge of the printed wiring board piece. That is, a point in the printed wiring board piece, in which the distance between the two intersections of this straight line and the outer peripheral edge is bisected by this point in all the straight lines passing through this point. means.

[Details of Embodiments of the present disclosure]
Hereinafter, the flexible printed wiring board array according to the present disclosure, a method for manufacturing the same, and an embodiment of the flexible printed wiring board will be described in detail with reference to the drawings.

[First Embodiment]
[Flexible printed wiring board array]
As shown in FIG. 1, the flexible printed wiring board array 1 of the present embodiment has a plurality of printed wiring board pieces 3 arranged. The flexible printed wiring board array 1 typically has a rectangular shape in a plan view. The flexible printed wiring board array 1 is divided into a plurality of printed wiring board pieces 3. The plurality of printed wiring board pieces 3 are arranged so as to be in contact with each other regularly and without gaps in a plan view. Usually, a dozen to several hundred printed wiring board pieces 3 are arranged in the flexible printed wiring board array 1. In FIG. 1, in order to help understanding the area occupied by each printed wiring board piece 3, each area of each of the three printed wiring board pieces 3 is surrounded by a thick line to illustrate.

[Printed circuit board pieces]
As is clear from reference to FIG. 4, each printed wiring board piece 3 has a base film 5, a first conductive pattern 9 laminated on the base film 5, and a first in the base film 5. A second conductive pattern 11 that is laminated in a region other than the laminated region of the conductive pattern 9 and is not electrically connected to the first conductive pattern 9 is provided.

The printed wiring board piece 3 includes a wiring board area 20 which is a region cut out as a flexible printed wiring board. In the embodiment shown in FIGS. 1 and 2, the printed wiring board piece 3 has a rectangular shape in a plan view. The cut-out flexible printed wiring board (that is, the wiring board area 20) is also rectangular in a plan view. All the printed wiring board pieces 3 are connected to each other via the base film 5. The printed wiring board piece 3 may have an outer edge region 7 that surrounds all or part of the wiring board region 20.

In the embodiment shown in FIGS. 1 and 2, among the plurality of printed wiring board pieces 3, a plurality of first prints arranged along the outer peripheral edge of the flexible printed wiring board array 1 (that is, the entire base film 5). The wiring board piece 3a has an outer edge region 7 as shown in the hatching (shading) of FIG. 1 and FIG. That is, the first printed wiring board piece 3a has a wiring board region 20 and an outer edge region 7. In FIG. 3, reference numeral C indicates a cut line (virtual line) when the wiring board region 20 is cut.

Of these, in the four first printed wiring board pieces 3a located at the corners of the flexible printed wiring board array 1, the outer edge region 7 is in contact with two sides of the outer peripheral edge of the wiring board region 20. The area occupied by the first printed wiring board piece 3a is illustrated by surrounding the first printed wiring board piece 3a located at the upper left of FIG. 1 with a thick line. Further, the outer edge region 7 is illustrated by hatching (shaded wire) on the first printed wiring board piece 3a surrounded by the thick line.

In the plurality of first printed wiring board pieces 3a located between the four first printed wiring board pieces 3a at the corners, the outer edge region 7 is in contact with one side of the outer peripheral edge of the wiring board area 20. The area occupied by the first printed wiring board piece 3a is illustrated by surrounding the first printed wiring board piece 3a located third from the upper left to the bottom of FIG. 1 with a thick line. Further, the outer edge region 7 is illustrated by hatching (shaded wire) on the first printed wiring board piece 3a surrounded by the thick line.

On the other hand, among the plurality of printed wiring board pieces 3, the plurality of second printed wiring board pieces 3b arranged inside the first printed wiring board pieces 3a do not have an outer edge region and are wired. It is composed of only the plate region 20. The area occupied by the second printed wiring board piece 3b is surrounded by a thick line around the second printed wiring board piece 3b located second from the upper left to the bottom in FIG. 1 and fourth from the right. Illustrate.

As shown in FIG. 1, when all the wiring board areas 20 of the first printed wiring board piece 3a and the second printed wiring board piece 3b are combined, a single rectangular wiring board area group is formed as a whole. When all the outer edge regions 7 of the first printed wiring board piece 3a are combined, it becomes one annular outer edge region group surrounding the wiring board region group.

In the first printed wiring board piece 3a, the outer edge region 7 is removed and the flexible printed wiring board is obtained by cutting out the wiring board region 20 along the cut lines C as illustrated on the right side and the left side of FIG. be able to. In the second printed wiring board piece 3b, a flexible printed wiring board can be obtained by cutting out the second printed wiring board piece 3b as it is along the cut line C as illustrated on the left side of FIG. In addition, "cutting out" includes cutting out.

The length of the printed wiring board piece 3 in the longitudinal direction and the lateral direction in the plan view is not particularly limited, and the size of the first conductive pattern 9 and the second conductive pattern 11 arranged on the printed wiring board piece 3 are not particularly limited. Is appropriately set according to the size of the outer edge region 7, the size of the outer edge region 7, and the like.

<Base film>
The base film 5 has an insulating property. The base film 5 is formed in a sheet shape. The base film 5 has a rectangular shape. As a whole, one base film 5 is partitioned corresponding to the printed wiring board piece 3. The overall shape of the base film 5 is rectangular and matches the shape of the flexible printed wiring board array 1.

Examples of the material of the base film 5 include a flexible resin containing polyimide, a liquid crystal polymer, a fluororesin, polyethylene terephthalate, polyethylene naphthalate, or the like as a main component. Among these, a resin containing polyimide as a main component is particularly preferable because it is excellent in insulating properties and mechanical strength. The "main component" means a component having the largest content in terms of mass, for example, a component having a content of 50% by mass or more.

The thickness of the base film 5 is set depending on the intended use of the flexible printed wiring board to be cut out and is not particularly limited. For example, the lower limit of the average thickness of the base film 5 is preferably 5 μm, more preferably 12 μm. .. On the other hand, the upper limit of the average thickness of the base film 5 is preferably 2 mm, more preferably 1.6 mm. If the average thickness of the base film 5 is less than the above lower limit, the strength of the base film 5 and thus the flexible printed wiring board array 1 may be insufficient. On the contrary, when the average thickness of the base film 5 exceeds the above upper limit, the flexible printed wiring board array 1 may become unnecessarily thick.

As the lower limit of the average length in the longitudinal direction in the plan view of the base film 5, 30 cm is preferable, and 50 cm is more preferable. On the other hand, the upper limit of the average length in the longitudinal direction is preferably 150 cm, more preferably 100 cm. If the average length in the longitudinal direction is less than the lower limit, the quantity of the printed wiring board piece 3 may decrease, and the production efficiency thereof may become insufficient. On the contrary, when the average length in the longitudinal direction exceeds the upper limit, the cost of the manufacturing equipment of the flexible printed wiring board array 1 may become excessive.

As the lower limit of the average length in the lateral direction in the plan view of the base film 5, 10 cm is preferable, and 20 cm is more preferable. On the other hand, the upper limit of the average length in the lateral direction is preferably 120 cm, more preferably 80 cm. If the average length in the lateral direction is less than the above lower limit, the quantity of the printed wiring board piece 3 may decrease, and the production efficiency thereof may become insufficient. On the contrary, when the average length in the lateral direction exceeds the upper limit, the cost of the manufacturing equipment of the flexible printed wiring board array 1 may become excessive.

<1st conductive pattern>
The first conductive pattern 9 is formed of a conductive material into a predetermined shape. The first conductive pattern 9 is energized and constitutes wiring. In the embodiment shown in FIGS. 1 and 2, as shown in FIG. 3, the first conductive pattern 9 is laminated on one surface of the base film 5, but is also laminated on both surfaces of the base film 5. You may. In the embodiment shown in FIGS. 1 and 2, the printed wiring board piece 3 has a plurality of (here, four) first conductive patterns 9, but the first conductive pattern 9 in the printed wiring board piece 3 The quantity may be 1 or more, and is not particularly limited. When the printed wiring board piece 3 has a plurality of first conductive patterns 9, the plurality of first conductive patterns 9 are electrically connected to each other.

Examples of the material of the first conductive pattern 9 include metals such as copper, gold, silver, nickel, and iron, and alloys containing them. Of these, copper, which is relatively inexpensive and has a high conductivity, is preferable.

The lower limit of the average thickness of the first conductive pattern 9 is preferably 5 μm, more preferably 20 μm, and even more preferably 30 μm. On the other hand, the upper limit of the average thickness is preferably 350 μm, more preferably 280 μm. If the average thickness is less than the lower limit, the first conductive pattern 9 may be easily damaged. On the contrary, when the average thickness exceeds the upper limit, the variation in the thickness of the first conductive pattern 9 may become too large.

The shape of the first conductive pattern 9 in a plan view is appropriately set according to its function, and is not particularly limited.

The size of the first conductive pattern 9 in a plan view is appropriately set based on the circuit design, but if it is allowed in the circuit design, it is appropriately set so as to satisfy the condition of the length described later, for example. Is preferable.

The first conductive pattern 9 may have a function other than the function as wiring. For example, as shown in FIG. 2, a part of the first conductive pattern 9 may form a coil portion. This coil portion is a flat coil portion. Examples of the shape of the coil portion include an elliptical shape as shown in FIG. 2, a circular shape, and the like.

The coil portion usually has a curved shape in a plan view. Therefore, the gap between the first conductive patterns 9 and the gap inside the first conductive pattern 9 (inside the coil portion) are relatively large. That is, the easily bendable portion of the base film is relatively large. Therefore, when the second conductive pattern 11 is not arranged in this gap, the base film 5 is easily bent by heating or the like. However, since the second conductive pattern 11 is arranged in the region where the first conductive pattern 9 is not laminated, even if the base film 5 is easily bent due to the shape of the coil portion, the bending is suppressed. be able to. Therefore, when a part of the first conductive pattern 9 constitutes the coil portion, the effect of the flexible printed wiring board array 1 becomes more remarkable.

<Second conductive pattern>
The second conductive pattern 11 is formed of a conductive material into a predetermined shape. The second conductive pattern 11 is not energized and does not constitute wiring. That is, the second conductive pattern 11 does not have an electrical function. The second conductive pattern 11 is laminated in a region other than the laminated region of the first conductive pattern in the base film 5, and is not electrically connected to the first conductive pattern 9.

In the embodiment shown in FIGS. 1 and 2, as shown in FIG. 3, the second conductive pattern 11 is located in a region other than the laminated region of the first conductive pattern 9 on the surface on which the first conductive pattern 9 of the base film 5 is laminated. Are laminated. However, in addition, the second conductive pattern 11 may be laminated on a region other than the laminated region of the first conductive pattern 9 on the surface of the base film 5 on which the first conductive pattern 9 is not laminated. In this case, the second conductive pattern 11 may partially overlap with the first conductive pattern 9 with the base film 5 interposed therebetween.

In the embodiment shown in FIGS. 1 and 2, the printed wiring board piece 3 has a plurality of second conductive patterns 11. Specifically, the first printed wiring board 3a has six second conductive patterns 11, and the second printed wiring board 3b has five second conductive patterns 11. However, the number of the second conductive patterns 11 in the printed wiring board piece 3 may be 1 or more, and is not particularly limited.

In FIGS. 1 and 2, when the second conductive patterns 11 arranged in the outer edge region 7 of all the first printed wiring board pieces 3a are combined, the annular conductivity that surrounds all the wiring board regions 20 and is connected as a whole. It becomes a pattern. That is, the second conductive pattern 11 is formed so as to straddle the adjacent printed wiring board pieces 3a. In this case, when the flexible printed wiring board is cut out from the flexible printed wiring board array 1, the annular conductive pattern is cut.

Examples of the material of the second conductive pattern 11 include metals such as copper, gold, silver, nickel, and iron, and alloys containing them. Of these, copper, which is relatively inexpensive and has a high conductivity, is preferable.

The lower limit of the average thickness of the second conductive pattern 11 is preferably 5 μm, more preferably 20 μm, and even more preferably 30 μm. On the other hand, the upper limit of the average thickness is preferably 350 μm, more preferably 280 μm. If the average thickness is less than the lower limit, the second conductive pattern 11 may be easily damaged. On the contrary, when the average thickness exceeds the upper limit, the variation in the thickness of the second conductive pattern 11 may become too large.

The shape of the second conductive pattern 11 in a plan view is not particularly limited, and is appropriately set so as to suppress bending of the flexible printed wiring board array 1. As the second conductive pattern 11, a solid pattern or a grid pattern is preferable. For example, in the embodiment shown in FIG. 2, the second conductive pattern 11 is a solid pattern. When the second conductive pattern 11 is a solid pattern or a grid pattern, the second conductive pattern 11 can be easily laminated in a wider area in the region where the first conductive pattern 9 is not laminated in the base film 5. Therefore, the bending of the flexible printed wiring board array 1 is further suppressed.

As will be described later, considering that the second conductive pattern 11 can be formed at the same time as the first pattern 9, the material and average thickness of the second conductive pattern 11 are the same as the material of the first conductive pattern 9. It should be the same as the average thickness.

The size of the second conductive pattern 11 in a plan view is appropriately set so that bending of the flexible printed wiring board array 1 is suppressed. It is preferable that this size is appropriately set so as to satisfy the condition of the length described later, for example.

<Size of the first and second conductive patterns on the printed wiring board pieces>
As described above, the size of the second conductive pattern 11 in the printed wiring board piece 3 may be appropriately set so as to suppress the bending of the flexible printed wiring board array 1. For example, the size of the second conductive pattern 11 may be set as follows. That is, in the reference straight line passing through the center of the printed wiring board piece 3, the total length M1 of the region intersecting at least one of the first conductive pattern 9 and the second conductive pattern 11 is the first conductive pattern 9 and the second conductive pattern 9. It is preferably larger than the total length M2 of the region that does not intersect the pattern 11. In other words, the ratio of M1 to M2 (M1 / M2) is preferably more than 0.3. The reference straight line is a straight line that passes through the center of the printed wiring board piece 3 and connects one end edge and the other end edge of the printed wiring board piece 3.

As shown in FIG. 2, in the first printed wiring board piece 3a (for example, the upper right of FIG. 2) located at the corner, the center thereof is the wiring board area 20 and the outer edge in contact with the two sides of the wiring board area 20. It is the center S1 on the outer peripheral edge of the entire region including the region 7, and the reference straight line L1 passing through the center S1 is used as the reference straight line. In the first printed wiring board piece 3a other than the corner portion (for example, the upper left of FIG. 2), the center thereof is the entire area including the wiring board area 20 and the outer edge area 7 in contact with one side of the wiring board area 20. It is the center S2 on the outer peripheral edge of the above, and the reference straight line L2 passing through the center S2 is used as the reference straight line. In the second printed wiring board piece 3b (for example, the lower left of FIG. 2), the center thereof is the center S3 on the outer peripheral edge of the second printed wiring board piece 3b itself corresponding to the wiring board area 20, and is used as the reference straight line. , The reference straight line L3 passing through the center S3 is used.

In the embodiment shown in FIG. 2, the reference straight lines L1, L2, and L3 correspond to the diagonal lines of the outer peripheral edge of each printed wiring board piece 3, but each reference straight line may be a straight line other than the diagonal line. ..

As shown in FIG. 4, the total length M1 is the total length Mx of the region intersecting the first conductive pattern 9 and the second conductive pattern 11 in the reference straight line. The total length M2 is the total length My of the regions that do not intersect the first conductive pattern 9 and the second conductive pattern 11 in the reference straight line.

As described above, when the total length M1 of each printed wiring board piece 3 is larger than the total length M2, the easily bendable region of the flexible printed wiring board array 1 can be further reduced. Therefore, the bending of the flexible printed wiring board array 1 is further suppressed. From the viewpoint that bending is more suppressed in this way, it is preferable that M2 is larger than M1. For example, the lower limit of the ratio (M1 / M2) is preferably more than 0.3, more preferably 0.5. On the other hand, the upper limit of the above ratio is preferably 0.9.

If the above ratio does not reach the above lower limit, the bending of the flexible printed wiring board array 1 may not be sufficiently suppressed as described above. On the contrary, when the ratio exceeds the upper limit, the second conductive pattern 11 may be too close to the first conductive pattern 9, and both may be electrically connected to deteriorate the function of the first conductive pattern 9. .. In addition, in the first printed wiring board piece 3a, when the ratio exceeds the upper limit, the region occupied by the second conductive pattern 11 in the outer edge region 7 becomes too large as compared with the bending suppressing effect. The cost may be excessive.

[Manufacturing method of flexible printed wiring board array]
The method for manufacturing the flexible printed wiring board array 1 includes a step of laminating a first conductive pattern 9 and a second conductive pattern 11 that is not electrically connected to the first conductive pattern 9 on the base film 5. In the laminating step, the second conductive pattern 11 is laminated in a region other than the laminating region of the first conductive pattern 9 in the base film 5.

<Laminating process>

Specifically, in the laminating step, a plurality of first conductive patterns 9 and the first conductive pattern 9 are formed on the base film 5 (one base film as a whole) corresponding to the printed wiring board individual pieces 3. And a plurality of second conductive patterns 11 that are not electrically connected to each other are laminated. In this laminating step, the second conductive pattern 11 is laminated in a region other than the laminating region of the first conductive pattern 9 of the base film 5 corresponding to each printed wiring board piece 3.

As a method of laminating the first conductive pattern 9 and the second conductive pattern 11 on the base film 5, a subtractive method or a semi-additive method can be used.

In a typical subtractive method, first, a metal layer is laminated on the entire area occupied by the printed wiring plate piece 3 in the base film 5, for example, by bonding a metal foil, depositing a metal, sintering metal fine particles, or metal plating. To do. Next, the first conductive pattern 9 and the second conductive pattern 11 are formed by forming and etching a resist pattern that covers the portions corresponding to the desired first conductive pattern 9 and the second conductive pattern 11 in the metal layer. ..

When forming the resist pattern, the resist pattern is formed so that the arrangement of the second conductive pattern 11 is spaced from the first conductive pattern 9 and is not electrically connected to the first conductive pattern 9.

[Flexible printed wiring board]
The flexible printed wiring board is laminated on a region other than the base film 5, the first conductive pattern 9 laminated on the base film 5, and the laminated region of the first conductive pattern on the base film 5, and the first A conductive pattern 9 and a second conductive pattern 11 that are not electrically connected are provided.

As described above, the flexible printed wiring board is obtained through a separation step of cutting out a wiring board region 20 from the flexible printed wiring board array 1.

〔advantage〕
In the flexible printed wiring board array 1, since the printed wiring board piece 3 has the second conductive pattern 11 in addition to the first conductive pattern 9, the portion of the base film 5 that is easily bent is reduced, so that bending is suppressed. It will be. Therefore, the flexible printed wiring board array 1 is excellent in handleability.

According to the method for manufacturing the flexible printed wiring board array, the flexible printed wiring board array 1 described above can be manufactured. That is, the flexible printed wiring board array 1 having excellent handleability can be manufactured.

Similar to the flexible printed wiring board array 1 described above, the flexible printed wiring board has the second conductive pattern 11, so that the portion of the base film 5 that is easily bent is reduced, so that the bending is suppressed. Therefore, the flexible printed wiring board is excellent in handleability.

[Second Embodiment]
In the flexible printed wiring board array of the present embodiment, its manufacturing method, and the flexible printed wiring board, the shape of the second conductive pattern located in each wiring board region of the first printed wiring board piece and the second printed wiring board piece. Is different from the first embodiment. Since the other configurations are the same as those in the first embodiment, the same reference numerals are given and the description thereof will be omitted.

<Second conductive pattern>
In the present embodiment, the second conductive pattern located in the wiring board region of the printed wiring board piece is a grid pattern. Specifically, the second conductive pattern is a grid-like pattern formed along the outer peripheral edge of the printed wiring board piece. On the other hand, the second conductive pattern located in the outer edge region of the printed wiring board piece is a solid pattern as in the first embodiment.

Specifically, as shown in FIG. 5, in the flexible printed wiring board array 1a of the present embodiment, the second conductive pattern 31 located in the wiring board region 20 of the first printed wiring board piece 23a has a grid pattern. It is a pattern, and a plurality of linear patterns are formed so as to have a plurality of the same polygons (lattices) arranged regularly. The second conductive pattern 31 located in the wiring board region 20 of the second printed wiring board piece 23b is a grid pattern like the first printed wiring board piece 23a, and the grid pattern is regularly formed. A plurality of linear patterns are formed intersecting with each other so as to have a plurality of the same polygons (lattices) arranged. On the other hand, in both the first printed wiring board piece 23a and the second printed wiring board piece 3b, the second conductive pattern 31 located in the outer edge region 7 is located in the outer edge region 7 of the first embodiment. It is the same solid pattern as the conductive pattern 11. The polygon of the grid pattern is not particularly limited, and examples thereof include a triangle, a quadrangle, a pentagon, and a hexagon. Note that FIG. 5 shows a quadrangular aspect as an example of the polygon.

Since the other configurations of the second conductive pattern are the same as those of the second conductive pattern of the first embodiment, the description thereof will be omitted.

Here, for example, when forming a coating layer that covers the first conductive pattern 9 and the second conductive pattern 31, the length of the laminate of the base film 5, the first conductive pattern 9, and the second conductive pattern 31 is usually long. It is transported along the direction or the lateral direction. At this time, since the grids of the grid-like pattern are regularly arranged, the tension applied to the base film 5 can be absorbed by the gaps (grid gaps) of the linear patterns, so that the flexibility Bending of the printed wiring board array 1a is further suppressed. In the grid pattern, it is preferable that all sides of the polygon have the same length. That is, it is preferable that the polygon is a regular polygon. By having the same length of all sides in this way, bending of the flexible printed wiring board array 1a is further suppressed. Further, since the second conductive pattern 31 is a grid pattern as described above, it is possible to reduce the adverse effect on the function of the first conductive pattern 9 as compared with the solid pattern.

Also in the present embodiment, as in the first embodiment, the total length M1 of the region intersecting at least one of the first conductive pattern 9 and the second conductive pattern 31 in the reference straight line passing through the center of the printed wiring board piece. Is preferably larger than the total length M2 of the region that does not intersect with the first conductive pattern 9 and the second conductive pattern 31.

[Manufacturing method of flexible printed wiring board array]
In the present embodiment, the above-mentioned second conductive pattern 31 is laminated in place of the second conductive pattern 11 of the first embodiment. Other than that, it is the same as that of the first embodiment, and thus the description thereof will be omitted.

[Flexible printed wiring board]
The flexible printed wiring board of the present embodiment is laminated in a region other than the base film 5, the first conductive pattern 9 laminated on the base film 5, and the first conductive pattern 9 laminated region in the base film 5. A second conductive pattern 31 that is not electrically connected to the first conductive pattern 9 is provided.

The flexible printed wiring board is obtained through a separation step of cutting out a wiring board region 20 from the flexible printed wiring board array 1a as in the first embodiment.

〔advantage〕
Similar to the first embodiment described above, the flexible printed wiring board array 1a has a portion of the base film 5 that is easily bent because the printed wiring board pieces have the second conductive pattern 31 in addition to the first conductive pattern 9. Since the amount of bending is reduced, bending is suppressed. Therefore, the flexible printed wiring board array 1a is excellent in handleability.

In addition, in the flexible printed wiring board array 1a of the present embodiment, since the second conductive pattern 31 is a parallel line pattern, the adverse effect on the function of the first conductive pattern 9 is reduced as compared with the solid pattern. be able to. Further, the flexible printed wiring board array 1a is further suppressed in bending because the second conductive pattern 31 is a parallel line pattern in which the second conductive pattern 31 is inclined with respect to the outer edge of the printed wiring board pieces.

According to the method for manufacturing the flexible printed wiring board, the flexible printed wiring board array 1a described above can be manufactured.

Similar to the flexible printed wiring board array 1a described above, the flexible printed wiring board has the second conductive pattern 31, so that the portion of the base film 5 that is easily bent is reduced, so that the bending is suppressed. Therefore, the flexible printed wiring board is excellent in handleability.

In addition, similarly to the flexible printed wiring board array 1a described above, the flexible printed wiring board has a function of the first conductive pattern 9 as compared with the solid pattern because the second conductive pattern 31 is a parallel line pattern. It is possible to reduce the adverse effect on. Further, the flexible printed wiring board has a parallel line pattern in which the second conductive pattern 31 is inclined with respect to the outer edge of the printed wiring board piece 3, so that the bending is further suppressed.

[Other Embodiments]
It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive. The scope of the present invention is not limited to the configuration of the above embodiment, but is indicated by the scope of claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims. To.

The printed wiring board pieces in the flexible printed wiring board array may have a coating layer (cover lay) that covers the first conductive pattern and the second conductive pattern. Since the printed wiring board pieces have a coating layer in this way, it is possible to prevent the first conductive pattern and the second conductive pattern from being damaged during storage, transportation, or the like of the flexible printed wiring board array. Further, as described above, even if the coating layer is heated when it is formed, the flexible printed wiring board array can be prevented from bending due to the provision of the second conductive pattern. Therefore, the effect of the flexible printed wiring board array becomes more remarkable by providing the coating layer.

When the printed wiring board piece has the coating layer, in the method for manufacturing the flexible printed wiring board array, after performing the step of laminating the first conductive pattern and the second conductive pattern, the first conductive pattern and the first conductive pattern are performed. (2) A coating step of coating the coating layer on the conductive pattern may be provided. The flexible printed wiring board may also have a coating layer as described above.

The flexible printed wiring board array is not limited to a mode in which the first conductive pattern and the second conductive pattern are laminated on one surface of the base film, and the first conductive pattern is laminated on both surfaces of the base film. A mode in which the second conductive pattern is laminated on one surface, a mode in which the first conductive pattern is laminated on one surface of the base film, and a second conductive pattern is laminated on both surfaces, both of the base film. An embodiment in which the first conductive pattern is laminated on the surfaces and the second conductive pattern is laminated on both surfaces may be adopted.

Here, when the patterns are laminated on both sides of the base film as described above and these patterns overlap in a plan view, they intersect with the overlapping portion of the patterns in the reference straight line in the calculation of the total length M1. Add the lengths of the regions and do not double add the regions that intersect each pattern.

In the above embodiment, the second conductive pattern located in the outer edge region is formed so as to straddle the outer edge regions adjacent to each other. However, the second conductive pattern located in the outer edge region may not be formed so as to straddle the outer edge regions adjacent to each other. In this case, the second conductive patterns arranged in the outer edge region are not connected to each other, and when the flexible printed wiring board is cut out from the flexible printed wiring board array, the second conductive pattern located in the outer edge region is not cut.

In the above embodiment, the mode in which the second conductive pattern located in the outer edge region is a solid pattern is shown. However, the second conductive pattern located in the outer edge region may be a pattern having another shape such as a parallel line pattern. Further, the second conductive pattern located in the wiring board region may also have a shape other than the solid pattern and the parallel line pattern.

In the above embodiment, each piece of the first printed wiring board along the outer peripheral edge of the flexible printed wiring board array has an outer edge region surrounding a part of the wiring board region, and these outer edge regions are formed in an annular shape. Indicates an aspect of However, when the printed wiring board piece has an outer edge region, the mode of the outer edge region is not particularly limited. For example, all printed wiring board pieces may each have an outer edge region that surrounds the entire region of each wiring board.

The printed wiring board piece may have a second conductive pattern that is removed when the flexible printed wiring board is cut out, not only in the outer edge region but also in the wiring board region.

The shapes of the flexible printed wiring board array, the individual printed wiring board pieces, the outer edge region, the first conductive pattern, and the second conductive pattern are not limited to the above embodiments, and may be appropriately set.

In the flexible printed wiring board array, the base film of the first printed wiring board piece located at the four corners of the plurality of printed wiring board pieces has a shape in which the corners are chamfered. May be good. That is, the entire base film may be chamfered in a curved shape such that the outer peripheral edges of the four corners project outward. Along with this, when the printed wiring board pieces at the four corners have an outer edge region, the outer peripheral edge of the outer edge region of the first printed wiring board pieces at the four corners is formed in the chamfered shape. Will be done. Since the corners of the base film are curved as described above, the outer edge region of the individual printed wiring board pieces located at the corners is less likely to bend.

The flexible printed wiring board array according to the embodiment of the present disclosure, the flexible printed wiring board array manufactured by the manufacturing method thereof, and the flexible printed wiring board are excellent in handleability, and are therefore suitable for efficiently manufacturing a circuit. Used.

1,1a Flexible printed wiring board array 3 Printed wiring board piece 3a 1st printed wiring board piece 3b 2nd printed wiring board piece 5 Base film 7 Outer edge area 9 1st conductor pattern 11, 31 2nd conductor pattern 20 Wiring Board area

Claims (8)

A flexible printed wiring board array in which a plurality of printed wiring board pieces are arranged.
The above printed wiring board pieces
With the base film
The first conductive pattern laminated on the base film and
A flexible printed wiring board array including a second conductive pattern that is laminated in a region other than the laminated region of the first conductive pattern in the base film and is not electrically connected to the first conductive pattern. In the reference straight line passing through the center of the printed wiring board piece, the total length of the region intersecting at least one of the first conductive pattern and the second conductive pattern does not intersect with the first conductive pattern and the second conductive pattern. The flexible printed wiring board array according to claim 1, which is larger than the total length of the regions. The flexible printed wiring board array according to claim 1 or 2, wherein the printed wiring board pieces have an outer edge region. The flexible printed wiring board array according to claim 1, claim 2 or claim 3, wherein the second conductive pattern is a solid pattern or a grid pattern. The flexible printed wiring board array according to any one of claims 1 to 4, wherein a part of the first conductive pattern constitutes a coil portion. The flexible printed wiring board array according to any one of claims 1 to 5, wherein the printed wiring board piece further includes a coating layer that covers the first conductive pattern and the second conductive pattern. It is a manufacturing method of a flexible printed wiring board array in which a plurality of printed wiring board pieces are arranged.
The base film is provided with a step of laminating a first conductive pattern and a second conductive pattern that is not electrically connected to the first conductive pattern.
In the laminating step, a method for manufacturing a flexible printed wiring board array in which the second conductive pattern is laminated in a region other than the laminating region of the first conductive pattern in the base film. With the base film
The first conductive pattern laminated on the base film and
A flexible printed wiring board provided with a second conductive pattern laminated in a region other than the laminated region of the first conductive pattern in the base film and not electrically connected to the first conductive pattern.

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