JP2006059886A - Processing board and its manufacturing method, and method of manufacturing product board - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a processing board which endures automatic packaging without depending upon the quality of the material and can easily separate into individual product boards, and to provide a method of manufacturing a product board. <P>SOLUTION: The processing board 10 includes a frame part 12, pushback boards 14, 14... temporarily stopped to the frame part 12 and V cut boards 16, 16..., first V cuts 18, 18 and second V cuts 20, 20... communicating with the periphery of at least the pushback boards 14, 14... and the V cut boards 16, 16..., and first V cuts 18, 18 and second V cuts 20, 20... communicating with the outer periphery of the frame part 12, and fillers 22, 22..., filled in at least part of the first V cuts 18, 18 and the second V cuts 20, 20.... <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a method of manufacturing a processed board and a product board, and more specifically, one or more pushback boards and / or V pushed back from a mother board (for example, a printed wiring mother board, a metal board, etc.). The present invention relates to a processed board (for example, a mounting board or the like) including a product board (for example, a printed circuit board or the like) made of a V-cut board temporarily fixed to a frame portion by cutting, and a method for manufacturing such a product board. .

  In recent years, with the miniaturization of electronic devices, there has been an increasing demand for miniaturization and modification of printed circuit boards used in electronic devices. On the other hand, an electronic component automatic mounting machine (hereinafter referred to as “self-mounting machine”) such as a chip mounter or an automatic insertion machine for mounting electronic components on a printed circuit board is referred to as the size of a workpiece because of its conveyance. Have upper and lower limits. In addition, the external shape of the workpiece used in the self-machine is required to be substantially rectangular, that is, at least one side is a straight line, and all or a part of the side perpendicular to the straight line is required to be a straight line. The

  Therefore, when mounting electronic components on a small and irregular printed circuit board using a self-mounting machine, first, a plurality of printed circuit boards are formed on the printed wiring board, and the V-cut method and pushback method are used. Using a perforation method, etc., the printed circuit board is temporarily fixed to the original printed wiring board, and then the printed wiring board has a size and shape that can be conveyed by the self-equipment. A method of cutting a substrate (mounting substrate) is used.

Of these, the V-cut method uses a V-shaped groove (V-cut) along the boundary of the printed circuit printed on the printed wiring board, mounts electronic components on the printed circuit, and then cuts the V-cut. It is a method of breaking along.
In the pushback method, the printed circuit board is punched by using a blade having a predetermined shape while holding the printed wiring board between the upper mold and the lower mold, and then the punched printed circuit board is removed from the original hole. It is a method of fitting.
Further, the perforation method is a method in which a large number of small holes are formed along the boundary line of the printed circuit board, and the holes are broken along the small holes.

Each of these processing methods has advantages and disadvantages. For example, the pushback method is not particularly limited in the shape of the printed circuit board, and thus is an effective method especially when electronic components are automatically mounted on an irregular printed circuit board. However, the pushback method generally causes a large warp in the substrate after processing, and the material yield is also low.
On the other hand, the V-cut method has little warping of the substrate and a high material yield, but can be applied only to a printed circuit board having a linear outer shape and cannot be applied to an irregular printed circuit board.
Further, the perforation method is simple, but has a drawback that the accuracy of the external dimensions of the printed circuit board is low.

  In order to solve this problem, various methods have been conventionally proposed. For example, Patent Document 1 discloses a printed wiring board in which a printed circuit board punched out from a printed wiring board is fitted into the original hole, and a plurality of slits are provided at the ears of the printed wiring board. Is disclosed. This document discloses that warp that occurs during pushback processing can be reduced by providing a plurality of slits in the ears of the printed wiring board.

Further, in Patent Document 2, a U-shaped slit (through hole) is provided in a portion protruding in a convex shape, and the bottom of the portion protruding in a convex shape is V along a boundary line with an unnecessary substrate. A printed circuit board having grooves is disclosed.
Patent Document 3 discloses a multi-sided printed wiring board in which perforations are formed around a single substrate and shallow concave grooves are formed around the perforations. This document describes that by forming a shallow concave groove around the perforation, peeling of the substrate can be suppressed when breaking along the perforation.

  Further, Patent Document 4 discloses a printed circuit board in which a mark indicating a stop position is formed in front of a V groove processing stop position on a V groove processing line formed on the printed circuit board. In this document, when the V-groove processing ends in the middle from the edge to the edge of the substrate, if the mark is provided in front of the processing stop position, the processing stop position can be confirmed by visual observation. The point that can be stopped is described.

JP 2001-267700 A FIG. 1 of Japanese Patent Laid-Open No. 5-160539 FIG. 1 of Japanese Utility Model Laid-Open No. 4-38071 Fig. 3 of Japanese Utility Model Publication No. 63-73964

  Currently, resin boards are the mainstream of printed circuit boards used in various electrical devices. Since the resin substrate is hard and fragile, even if a large number of V cuts are formed on the surface of the resin substrate, the strength and flatness that can withstand automatic mounting can be maintained. Further, the substrate can be easily cracked simply by applying a bending stress along the V-cut, and can be easily separated into individual printed circuit boards. Furthermore, when the resin substrate is subjected to pushback processing, the printed circuit board can be easily cracked and the printed circuit board can be removed relatively easily by simply pushing out the printed circuit board from the frame or applying bending stress to the frame. be able to.

  On the other hand, metal substrates (for example, aluminum substrates) are also used for special applications (for example, applications that require high heat dissipation characteristics). If the above-described V-cut method or pushback method can be applied to this metal substrate, the manufacturing cost of the metal substrate can be greatly reduced.

However, the metal substrate has lower hardness and higher toughness than the resin substrate. Therefore, when forming a V-cut from one end to the other end of the metal substrate, if the depth of the V-cut increases, the metal substrate can be easily bent along the V-cut during handling, and can withstand automatic mounting. Strength and flatness cannot be maintained.
On the other hand, if the depth of the V-cut is reduced, the strength and flatness that can withstand automatic mounting can be maintained. However, even if a bending stress is applied to the metal substrate along the V-cut after the automatic mounting is completed, the substrate is only bent and is not easily separated into individual printed circuit boards. In extreme cases, it is difficult to even bend the metal substrate.
Further, when the pushback method is applied to the metal substrate, it is not easy to push out the printed circuit board from the frame part without deforming the printed circuit board because the fastening force by the frame part is strong. Further, even if bending stress is applied to the frame portion, the frame portion only bends and does not break, and it is not easy to separate the printed circuit board from the frame portion.

  Further, examples in which various problems as described above are solved, and a V-cut method and / or pushback method suitable for a metal substrate, and a processed plate obtained by using these methods have been proposed in the past. Not.

The problem to be solved by the present invention is a processed board (for example, a mounting board) that can withstand automatic mounting and can be easily separated into individual product boards (for example, printed circuit boards) regardless of the material. Is to provide.
Another problem to be solved by the present invention is to provide a method of manufacturing a product plate that can easily and inexpensively separate the product plate regardless of its material.

In order to solve the above problems, a processed plate according to the present invention communicates with a frame portion, a product plate temporarily fixed to the frame portion, at least around the product plate, and with an outer periphery of the frame portion. The present invention is characterized by comprising one or two or more V-cuts and a filler filled in at least a part of at least one of the V-cuts.
In this case, the filler preferably contains a resin. The product plate may be a V-cut plate temporarily fixed to the frame portion and / or another adjacent product plate via the V-cut. The product plate may be a pushback plate that is punched from a mother plate including the frame portion and temporarily fixed to the frame portion by being fitted into the original hole.
Moreover, the manufacturing method of the product board which concerns on this invention makes it a summary to fracture | rupture a frame part along V cut with which the processed board which concerns on this invention is equipped, and to separate a product board from a frame part.

  At least a part of at least one V-cut when a V-cut is formed which communicates with the periphery of the product plate temporarily fixed to the frame by the pushback method or the V-cut and communicates with the outer periphery of the frame. When the filler is filled in, the bending rigidity around the V-cut increases. Therefore, even if the processed plate is made of a metal substrate, the strength and flatness that can withstand automatic mounting can be maintained. Moreover, after the automatic mounting is finished, if the frame part is simply bent along the V-cut, or if the frame part is bent along the V-cut after removing the filler with an appropriate tool or chemical, the product plate It can be separated very easily.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. In the following description, a printed wiring board, a printed circuit board (pushback board, V-cut board) obtained by processing the printed wiring board, and a mounting board on which the printed circuit board is temporarily fixed will be described. An example to which the invention is applied will be described. The present invention relates to a “mother board” other than a printed wiring board, a “product board” other than a printed circuit board obtained by processing the same, and such a product board. The present invention can also be applied to “processed plates” other than the mounting substrate to which is temporarily fixed. In addition, the present invention is particularly effective when applied to a metal substrate, but can naturally also be applied to a resin substrate.

  FIG. 1 (a), FIG. 1 (b), FIG. 1 (c) and FIG. 1 (d) respectively show a plan view of a mounting substrate according to the first embodiment of the present invention, and A BB 'line sectional view, its CC' line sectional view, and its DD 'line sectional view are shown. In FIG. 1, the dimensions of each part are appropriately enlarged / reduced from the actual dimensions for easy viewing.

  In FIG. 1, a mounting substrate 10 according to the present embodiment includes a frame portion 12 and product plates (pushback plates 14, 14... And V-cut plates 16, 16...) Temporarily fixed to the frame portion 12. One or more V-cuts (first V-cuts 18, 18 and second V-cuts 20, 20,...) Communicating at least with the outer periphery of the product plate and also with the outer periphery of the frame portion 12, and each V-cut It is provided with fillers 22, 22... Filled at least in part.

The frame portion 12 is for supporting these until the automatic mounting on the pushback plates 14, 14... And the V cut plates 16, 16. At the four corners of the frame portion 12, through holes 12a, 12a,... Serving as reference holes and sub-reference holes for automatic mounting are formed.
Further, one or more slits 12b, 12b that communicate with the outer periphery of the frame 12 and that do not communicate with the pushback plates 14, 14... And the V cut plates 16, 16. ... is formed. The slits 12b, 12b... Are for reducing warpage that occurs during pushback processing. Therefore, the optimal number and length of the slits 12b, 12b... Are selected according to the degree of warpage generated on the mounting substrate 10. In addition, when there is little curvature, you may abbreviate | omit slit 12b, 12b ....

In the frame 12, pushback plates 14, 14... And V cut plates 16, 16... Are alternately arranged along the longitudinal direction of the first V cuts 18, 18. The ends are pushback plates 14 and 14, respectively.
The pushback plates 14, 14... Are punched out from a printed wiring board (mounting board before cutting the outer shape) and fitted into the original holes. The left and right ends of each pushback plate 14, 14... Are supported by the frame portion 12, and the upper and lower ends thereof are supported by the frame portion 12 or the adjacent V-cut plates 16, 16.
The V-cut plates 16, 16... Are areas that remain after the push-back plates 14, 14... Are punched from the mother board at a predetermined interval, and the left and right first V-cuts 18, 18 and the adjacent upper and lower push-back plates. 14, 14 is an area surrounded by 14. The V cut plates 16, 16... Are temporarily fixed to the frame portion 12 via the left and right first V cuts 18, 18.

Further, in the present embodiment, each pushback plate 14, 14... Is formed by integrating two or more first unit plates 14 a, 14 a. In addition, each V-cut plate 16, 16... Is formed by integrating two or more second unit plates 16 a, 16 a. The first unit plates 14a, 14a ... and the second unit plates 16a, 16a ... are printed circuit boards (product boards) which are final products.
The first shared straight line portion and the second shared straight line portion are arranged on a straight line, and the second V cuts 20, 20... Are formed on or near the second V cuts. Each first unit plate 14a, 14a... And each second unit plate 16a, 16a... Are appropriately formed with pin holes, through holes and the like for mounting electronic components.

In FIG. 1, the first unit plates 14a, 14a... And the pushback plates 14, 14 including the same, and the second unit plates 16a, 16a. Is also rectangular, but this is merely an example, and a shape including a curve may be used.
For example, the upper and lower sides of the pushback plates 14, 14... May include curves. In this case, the upper and lower sides of the V-cut plates 16, 16,.
Further, for example, the pushback plates 14, 14... In this case, the first V cuts 18 and 18 may be formed so as to contact the left and right sides of the arc shape.
Further, the left and right sides of the V-cut plates 16, 16... Only need to include straight lines, and it is not necessary for all of them to be straight lines. In this case, when a through hole having a predetermined shape is appropriately formed in the vicinity of both ends of the V-cut plates 16, 16... (And the pushback plates 14, 14...), The shapes in the vicinity of both ends of the pushback plates 14, 14. The shape in the vicinity of both ends of the V-cut plates 16, 16.

In FIG. 1, “first unit plates 14a, 14a... And second unit plates 16a, 16a...”, “Pushback plates 14, 14. 14 ”and“ V cut plates 16, 16... ”Have the same shape, but they may be different from each other.
For example, the pushback plates 14, 14... And the V cut plates 16, 16... Have the same width, and the first V cuts 18 and 18 are formed in parallel with each other. The lateral width of the plates 16, 16... May be monotonously increased or decreased along the longitudinal direction of the first V cuts 18. In this case, the first V cuts 18 and 18 formed at both ends of the pushback plates 14, 14... Are not parallel to each other.
Similarly, instead of forming the second V-cuts in parallel with each other, forming the first unit plates 14a, 14a,... And the second unit plates 14b, 14b,. You can also.

The first V cuts 18, 18 are formed on or near the boundary line (common tangent line) between each pushback plate 14, 14 ... and the frame portion 12, and at both ends of each pushback plate 14, 14 .... .
Here, “the vicinity of the common tangent” means a position that does not affect the shape and quality of each pushback plate 14, 14... And each V-cut plate 16, 16. The first V-cuts 18 and 18 are most preferably formed immediately above the common tangent line, but the surface of the push-back plates 14, 14... And the V-cut plates 16, 16. This means that the printed circuit formed on the surface and the electronic components mounted on the surface thereafter may be slightly shifted from the common tangent to the right and left as long as they are not damaged.

Similarly, each first shared straight line portion and each second shared straight line portion are arranged on a straight line, and the second V-cuts 20, 20... Are on or in the first shared straight line portion and the second shared straight line portion. It is formed in the vicinity.
Here, “the vicinity of the first shared straight line portion and the second shared straight line portion” refers to a position that does not affect the shape and quality of the first unit plates 14a, 14a... And the second unit plates 16a, 16a. . The second V-cuts 20, 20... Are most preferably formed directly above the first shared straight line portion and the second shared straight line portion, but the first unit plates 14a, 14a... And the second unit plates 16a, 16a. When high dimensional accuracy is not required, from the first shared straight line portion and the second shared straight line portion as long as the printed circuit formed on the surface and the electronic components mounted on the surface thereafter are not damaged. It means that it may be slightly shifted left and right.

Furthermore, both ends of the first V-cuts 18 and 18 extend from the end portions of the pushback plates 14 and 14 disposed above and below toward the outer periphery of the frame portion 12 and communicate with the outer periphery of the frame portion 12. Also, the upper and lower ends of the first V cuts 18 and 18 in the frame portion 12 are filled with fillers 22, 22. Also, the first V-cuts 18, 18 formed on the back surface are filled with fillers 22, 22 ... at substantially the same position as the front surface.
Similarly, both ends of the second V cuts 20, 20... Penetrate through the end sides of the pushback plates 14, 14 arranged above and below, extend toward the outer periphery of the frame portion 12, and communicate with the outer periphery of the frame portion 12. Yes. Further, the ends of the second V cuts 20, 20... In the frame portion 12 are filled with fillers 22, 22. Also, the second V-cuts 20, 20... Formed on the back surface are filled with fillers 22, 22.

  The length (filling length) and the number of fillers 22, 22... Filled in the V-cut maintain strength and flatness that can withstand automatic mounting, and facilitate the cutting operation of the frame portion 12. In addition, the optimum length and number are selected in accordance with the use and material of the mounting substrate 10 and the weight of components mounted on the mounting substrate 10. In general, the longer the filling length and / or the greater the number of fillers, the easier it is to maintain strength and flatness that can withstand automatic mounting, but the cutting work of the frame portion 12 becomes more complicated. There is a case.

For example, in the case of the mounting substrate 10 on which relatively lightweight components are mounted, as shown in FIG. 1, a filler 22 is provided at both ends of each first V cut 18, 18... And each second V cut 20, 20. Instead of filling 22 ..., each of the first V cuts 18, 18 and each of the second V cuts 20, 20 ... just fills one filler 22, 22, ... with a relatively short filling length. good. In this case, the fillers 22, 22... May be filled into the end of the V-cut (within the V-cut in the frame 12), or as long as it does not hinder automatic mounting or the like. One of the central portions may be filled.
In this case, the fillers 22, 22... May be filled only at one end of each V-cut formed substantially in parallel, or a certain V-cut is filled with the filler 22 at the upper end, and the like. In the V-cut, the position of the fillers 22, 22... May be changed for each V-cut, for example, the lower end is filled with the filler 22.

On the other hand, in the case of the mounting substrate 10 on which relatively heavy components are mounted, each V-cut may be filled with one filler 22, 22,... Having a relatively long filling length. Alternatively, a plurality of fillers 22, 22... Having a relatively short filling length or a long filling length may be filled for each V-cut. In this case, as shown in FIG. 1, a plurality of fillers 22, 22... May be filled at the end of the V-cut, or the center of the V-cut as long as automatic mounting or the like is not hindered. Any of the portions may be filled.
Further, in the case of the mounting substrate 10 on which particularly heavy components are mounted, the fillers 22, 22... May be filled over the entire length of each V-cut as long as automatic mounting or the like is not hindered. good.

Further, the fillers 22, 22... Do not necessarily have to be filled in the recesses of each V-cut without a gap. In short, it is only necessary to fill the mounting substrate 10 so that deformation of the mounting substrate 10 can be suppressed when bending stress acts on the mounting substrate 10 with the V-cut as the center.
Further, the fillers 22, 22... Do not necessarily need to be filled along the longitudinal direction of each V-cut, and may be filled in a concave groove formed so as to intersect the V-cut.
Further, the surfaces of the fillers 22, 22... Do not necessarily have to be substantially flush with the surface of the mounting substrate 10. In short, the surface of the fillers 22, 22... Is higher than the surface of the mounting substrate 10 as long as it does not interfere with automatic mounting and the like and can maintain strength and flatness that can withstand automatic mounting. Or it may be low.

The material of the fillers 22, 22... Is not particularly limited, depending on the V-cut cross-sectional shape, the material of the mounting substrate 10, the required bending rigidity, the thermal history exposed in the subsequent process, etc. Choose the best one. The fillers 22, 22, resist bending stress generated in the mounting substrate 10 during handling, can maintain the flatness of the mounting substrate 10, and have such strength that the product plate can be easily separated. What is necessary is just to have.
Among them, a material containing a resin is particularly suitable as a material for the fillers 22, 22... Because it is easy to fill and solidify the V-cut and separate the product plate. In this case, the fillers 22, 22... May be made of only a resin, or may contain an appropriate filler.
Further, since the mounting substrate 10 is generally heated in a subsequent process (for example, a soldering process), it is preferable to use a resin having heat resistance corresponding to the heating temperature for the fillers 22, 22. Specific examples of such a resin include a thermosetting resin, a two-component curable resin, a light (ultraviolet light, visible light, etc.) curable resin, and a heat drying resin.
For example, when the mounting substrate 10 is made of aluminum or an alloy thereof, the aluminum is corroded by the alkaline solution. Therefore, in such a case, it is preferable to use a resin that does not use an alkaline solution when filling the V-cut, solidifying, or the like.

The first V cuts 18, 18 and the second V cuts 20, 20,... Are preferably formed on the upper and lower surfaces of the mounting substrate 10, as shown in FIG. As long as it is not, it may be formed only on one of the surfaces.
When the first V cuts 18 and 18 and the second V cuts 20, 20... Are formed on both surfaces of the mounting substrate 10, the fillers 22, 22. You may fill only the V-cut formed in the surface. In the case of filling only one side of the V-cut, it is preferable to fill the mounting substrate 10 on the side where the mounting substrate 10 is likely to have an acute angle.
In order to increase the bending rigidity of the mounting substrate 10, it is preferable to fill all the V-cuts formed on the mounting substrate 10 with fillers 22, 22... For V-cuts formed in non-parts, bent parts that do not interfere with subsequent processes even if bent, filling with fillers 22, 22... May be omitted.

Further, as shown in FIG. 1, the first V cuts 18, 18 and the second V cuts 20, 20,... Are preferably V-shaped with apex angles of about 30 to 50 °, but the bottoms are U-shaped. It may have a mold cross section.
Further, the cutting depths of the first V-cuts 18 and 18 and the second V-cuts 20, 20... Facilitate the cutting operation of the frame portion 12, the pushback plates 14, 14. It is preferable to define as follows. Since the mounting substrate 10 according to the present embodiment is filled with the fillers 22, 22... In each V-cut, the strength and flatness that can withstand automatic mounting even when the cutting depth is relatively deep. Can be maintained.

Next, the operation of the mounting substrate 10 according to the present embodiment will be described. In the mounting substrate 10 according to the present embodiment, the first V cuts 18 and 18 and the second V cuts 20, 20... Communicate with the outer periphery of the frame portion 12, and the filler 22 is provided in at least a part of each V cut. , 22... Are filled, the rigidity of the frame portion 12 is large.
Therefore, even when the mounting substrate 10 is made of a metal substrate, it is not bent along the V-cut during handling, and the strength and flatness that can withstand automatic mounting can be maintained. Moreover, even if the cutting depth of the V-cut is relatively deep, the strength and flatness that can withstand automatic mounting can be maintained.
Further, after the automatic mounting is completed, the frame portion 12 is simply bent along the V-cut, or the fillers 22, 22... Are removed using an appropriate tool or chemical, and then the frame portion 12 along the V-cut. .. And the V-cut plates 16, 16... Can be removed very easily.

  Further, the mounting substrate 10 according to the present embodiment has pushback plates 14, 14... And V-cut plates 16, 16... Alternately arranged, so that only the pushback method is used. High material yield.

  Furthermore, as shown in FIG. 1, a mounting board in which rectangular printed circuit boards having the same dimensions are arranged in the vertical and horizontal directions can be produced only by the V-cut method. However, in this case, it is necessary to perform V-cut processing along the vertical boundary line and the horizontal boundary line, respectively. However, since the mounting substrate 10 according to the present embodiment has the pushback plates 14, 14... And the V cut plates 16, 16. Therefore, the man-hour required for V-cut processing can be significantly reduced, and the manufacturing cost can be reduced.

  Next, a mounting board according to a second embodiment of the present invention will be described. 2 (a), 2 (b), and 2 (c), respectively, a plan view of the mounting substrate according to the present embodiment, a cross-sectional view taken along line BB ′, and CC 'Show cross-sectional view. In FIG. 2, the dimensions of each part are appropriately enlarged / reduced from the actual dimensions for easy viewing.

  2, the mounting substrate 30 according to the present embodiment communicates with a frame portion 32, V cut plates 34, 34... Temporarily fixed to the frame portion 32, and at least around the V cut plates 34, 34. And one or more V-cuts 36, 36... Communicating with the outer periphery of the frame portion 32, and fillers 38, 38. ing.

  The frame portion 32 is for supporting these until the automatic mounting on the V-cut plates 34, 34. In the four corners of the frame portion 32, through holes 32a, 32a... Serving as reference holes and sub reference holes for automatic mounting are formed.

  Each of the V cut plates 34, 34... Is composed of an area surrounded by four V cuts 36, 36..., And each of the V cut plates 34, 36. Temporarily secured to the board. The V-cut plates 34, 34... Are printed circuit boards (product boards) that are final products. Each V cut plate 34, 34... Is appropriately formed with pin holes, through holes, etc. for mounting electronic components, although not shown.

In addition, in FIG. 1, although the shape of each V cut board 34,34 ... is exhibiting the rectangular shape, this is a mere illustration and unevenness may exist in either of each side. In this case, in order to facilitate separation of the V-cut plates 34, 34..., It is preferable to appropriately combine pushback processing, drilling processing (such as punching processing using a die, router processing), perforation processing, and the like.
Further, the V cuts 36, 36... Arranged in the vertical direction and the V cuts 36, 36... Arranged in the horizontal direction may be formed in parallel with each other according to the shape of the V cut plates 34, 34. Alternatively, they may be formed non-parallel to each other.

The both ends of the V cuts 36, 36... Extend from the end portions of the V cut plates 34, 34, toward the outer periphery of the frame portion 32, and communicate with the outer periphery of the frame portion 32. Further, the upper and lower ends and the left and right ends of the V cuts 36, 36,... In the frame portion 32 are filled with fillers 38, 38, respectively. Also, V-cuts 36 formed on the back surface are filled with fillers 38, 38 at substantially the same position as the front surface.
In the example shown in FIG. 2, the two V-cuts 36, 36... Are filled with two fillers 38, 38... Having a relatively short filling length, but this is merely an example. The filling length, the number, the filling position, etc. of each of the fillers 38, 38... Can be arbitrarily selected according to the material and use of the mounting board 30 and the weight of components mounted on the mounting board 30. it can. In addition, the other points regarding the V-cuts 36, 36... And the fillers 38, 38.

Next, the operation of the mounting substrate 30 according to the present embodiment will be described. In the mounting substrate 30 according to the present embodiment, the V cuts 36, 36... Communicate with the outer periphery of the frame portion 32, and at least a part of each V cut 36, 36. Since it is filled, the rigidity of the frame part 32 is large.
Therefore, even when the mounting substrate 30 is made of a metal substrate, or even when the cut depth of the V cuts 36, 36,... Is relatively deep, it is not bent along the V cut during handling. The strength and flatness that can withstand automatic mounting can be maintained.
Further, after the automatic mounting is completed, the frame portion 32 is simply bent along the V-cut, or the fillers 38, 38... Are removed using an appropriate tool or chemical, and then along the V-cuts 36, 36. By bending the frame portion 32, the V-cut plates 34, 34... Can be removed very easily.

  Next, a mounting board according to a third embodiment of the present invention will be described. 3 (a), FIG. 3 (b), and FIG. 3 (c), respectively, a plan view of the mounting substrate according to the present embodiment, a cross-sectional view taken along line BB ′, and CC 'sectional view taken on the line is shown. In FIG. 3, the dimensions of each part are appropriately enlarged and reduced from the actual dimensions for easy viewing.

  In FIG. 3, the mounting substrate 40 according to the present embodiment includes a frame portion 42, a first pushback plate 44 (unit plates 44 a and 44 b) and a second pushback plate 46 that are temporarily fixed to the frame portion 42. V cuts 48, 48... Communicating with at least the outer periphery of the first pushback plate 44 and / or the second pushback plate 46 and communicating with the outer periphery of the frame portion 42, and at least a part of each V cut. Filled fillers 50, 50...

The frame portion 42 is for supporting these until the automatic mounting on the first pushback plate 44 and the second pushback plates 46, 46. .. Are formed at the four corners of the frame portion 42 as reference holes and sub-reference holes for automatic mounting.
Further, one or two or more slits 42b communicating with the outer periphery of the frame portion 42 and not communicating with the first pushback plate 44 and the second pushback plates 46, 46,. 42b ... are formed. Since other points regarding the slit 42b are the same as those of the first embodiment, description thereof will be omitted.

The first pushback plate 44 and the second pushback plate 46 are both punched from a printed wiring board (a mounting board before cutting the outer shape) and fitted into the original holes. The periphery of the first pushback plate 44 and the second pushback plate 46 is supported by a frame portion 42, respectively.
Further, the first pushback plate 44 has an L shape, and the two unit plates 44a and 44b are integrated via a shared straight line portion. A V-cut 48 is provided on or in the vicinity of the shared straight line portion. Is formed. In the present embodiment, the two unit plates 44a and 44b and the second pushback plate 46 are printed circuit boards (product boards) as final products. Furthermore, although not shown, the first pushback plate 44 and the second pushback plate 46 are appropriately formed with pin holes, through holes, and the like for mounting electronic components.

  Note that the shapes of the first pushback plate 44 and the second pushback plate 46 shown in FIG. 3 are merely examples, and the V cuts 48, 48. The V-cuts 48, 48... Are not necessarily parallel to each other, and are formed on or near the tangent line (boundary line) of the first pushback plate 44 and / or the second pushback plate 46. The preferred point is the same as in the first embodiment.

Both ends of the V-cuts 48, 48... Extend from the end (or end side) of the first pushback plate 44 or the second pushback plate 46 toward the outer periphery of the frame portion 42, and extend to the outer periphery of the frame portion 42. Communicate. In addition, both ends of the V cuts 48, 48... In the frame portion 42 are filled with fillers 50, 50. Also, the V-cuts 48 formed on the back surface are filled with fillers 50, 50.
In the example shown in FIG. 3, two fillers 50, 50... That are relatively short in filling length are filled at both ends of each V-cut 48, 48. The filling length, the number, the filling position, etc. of each of the fillers 50, 50... Can be arbitrarily selected according to the material and use of the mounting board 40, the weight of components mounted on the mounting board 40, and the like. it can. Further, the other points regarding the V-cuts 48, 48... And the fillers 50, 50.

Next, the operation of the mounting substrate 40 according to the present embodiment will be described. In the mounting substrate 40 according to the present embodiment, the V cuts 48, 48... Communicate with the outer periphery of the frame portion 42, and the fillers 50, 50. Is filled, the rigidity of the frame portion 42 is large.
Therefore, even when the mounting substrate 40 is made of a metal substrate, or even when the cut depth of the V cuts 48, 48... Is relatively deep, it is not bent along the V cut during handling. The strength and flatness that can withstand automatic mounting can be maintained.
Further, after the automatic mounting is completed, the frame portion 42 is simply bent along the V cut, or the fillers 50, 50... Are removed using an appropriate tool or chemical, and then along the V cuts 48, 48. Thus, the first pushback plate 44 and the second pushback plate 46 can be easily removed and the first pushback plate 44 can be divided into unit plates 44a and 44b simply by bending the frame portion 42.

  Next, the manufacturing method of the processed plate which concerns on this invention is demonstrated. First, necessary processing is performed on the mother board using a known method. For example, in the case of a processed board that uses the pushback method, pushback processing is performed on the mother board. Also, pin holes, through holes, and the like necessary for mounting electronic components are formed on the mother board using press working, router working, or the like. Further, the outer shape of the mother board is processed as necessary to adjust the shape. Further, using a known method, a V-cut that communicates with the periphery of the product plate and communicates with the outer periphery of the frame portion is formed.

Next, the V-cut formed on the mother board is filled with a filler. The filling method of the filler is not particularly limited, and various methods can be used according to the width and cross-sectional shape of the V-cut, the production quantity of the processed plate, and the like.
For example, when the V-cut has a U-shaped cross section, has a relatively wide width (for example, about 1 mm), and the production quantity of processed plates is small, a solid filler such as a dice or rod May be directly fitted into the V-cut, or may be bonded with an appropriate adhesive (for example, a thermosetting adhesive, the same applies hereinafter).
For example, when the V-cut has a V-shaped cross section, a wedge-shaped solid filler may be directly fitted into the V-cut or bonded with an appropriate adhesive. In this case, in order to ensure the fitting and fixing of the filler, a protrusion is provided at the tip of the filler, a hole into which the protrusion can be inserted is provided in the V-cut, and the filler protrusion is provided in the hole in the V-cut. The filler may be fixed by inserting.
Further, for example, a concave groove may be formed so as to intersect with the V-cut, and a solid filler such as a dice or a rod may be directly fitted into the concave groove or bonded with an appropriate adhesive.
Also, for example, a liquid or putty-like filler is manually poured into a V-cut and / or into a groove formed so as to intersect with the V-cut, using a curing agent, heat, light, etc. The filler may be cured.

  In addition, when the width of the V-cut is relatively narrow and / or when the production quantity of processed plates is large, a screen printing method using ink (a liquid filler that becomes a solid by curing treatment) is suitable. is there. FIG. 4 shows an example of a filling method using a screen printing method.

First, as shown in FIG. 4A, a screen 62 is disposed above a mother board 60 on which V-cuts 60a, 60a,. As is well known, the screen 62 is obtained by forming an emulsion 62b in a predetermined pattern on the back surface of a shear 62a having a predetermined mesh.
In this case, the mesh of the shear 62a is preferably coarse. The coarser the mesh of the shear 62a, the more ink can be poured into the V-cuts 60a, 60a. Specifically, the mesh of the shear 62a is preferably 80 to 100 mesh. The material of the shear 62a is not particularly limited, but stainless steel is preferable. Since the stainless steel shear 62a is good for ink removal, the ink filling operation can be performed efficiently.

The emulsion 62b is for closing the eyes of unnecessary portions of the shear 62a and dropping the ink only on the necessary portions. In this case, the emulsion 62b is preferably thick. As the emulsion 62b becomes thicker, a larger amount of ink can be poured into the V-cuts 60a, 60a, etc. by one screen printing. Specifically, the thickness of the emulsion 60b is preferably 100 μm or more, more preferably 200 μm or more, still more preferably 300 μm or more, still more preferably 400 μm or more, and further preferably 500 μm or more.
In general, as the thickness of the emulsion 62b increases, it takes longer to expose the pattern of the emulsion 62b, so that the shape accuracy of the pattern of the emulsion 62b decreases. However, in the present invention, the shape accuracy of the printed pattern is not always necessary. Rather, by thickening the emulsion 62b, there is an advantage that a large amount of ink can be filled by one screen printing, and the ink filling operation can be made efficient.

Next, as shown in FIG. 4B, an appropriate amount of ink 64 a is put on the screen 62, and the surface of the screen 62 is traced with the squeegee 66. Thereby, the ink 64a is pushed down through the gap of the emulsion 62b, and the ink 64a is filled in at least a part of the V cuts 60a, 60a... According to a predetermined pattern.
When a sufficient amount of ink 64a cannot be filled by one screen printing, the screen printing may be repeated a plurality of times.

Here, as the ink used for forming the filler, specifically,
(1) Ink containing ultraviolet curable resin (for example, UV curable permanent hole filling ink (PTR-1004, PTR-1004, PTR-924W, PTR-626, etc.) manufactured by Mutual Application Chemical Industries, Ltd., solar ink production ( UV curable solder resist ink (UVR-150G M28-100PS, UVR-150G NT220, FOC-35 B4, UVR-150G AG5 etc.)
(2) Ink containing heat drying type resin (for example, heat drying type hole filling ink (PTR-329WS, PTR-402W, etc.) manufactured by Mutual Applied Chemical Industries, Ltd., heat drying type hole filling ink (manufactured by Taiyo Ink Manufacturing Co., Ltd.) EH-602 NSK, etc.)
(3) Ink containing thermosetting resin (for example, thermosetting solder resist ink (S-40 C518, S-222 X16K, etc.) manufactured by Taiyo Ink Manufacturing Co., Ltd.),
Etc. As described above, the type of resin contained in the ink is selected according to the material of the processed plate.
Among these, in particular, an ink containing an ultraviolet curable resin is suitable as an ink for forming a filler because it is relatively easy to handle.
These inks may be used as they are, or may be used by mixing an appropriate filler.

When the V-cuts 60a, 60a,... Are filled with the ink 64a and then the ink 64a is cured (for example, ultraviolet irradiation, heat treatment, etc.), as shown in FIG. The mother board 60 filled with the filler 68 at least in part is obtained. Further, when the unevenness of the filler 68 becomes a problem, the surface of the filler 68 may be flattened by using a means such as polishing.
In the case where all necessary processing such as outer shape processing has been performed on the base plate 60 in advance, the processing plate according to the present invention is completed by filling the V-cuts 60a, 60a. On the other hand, when an unprocessed portion remains, such as an outer shape process, the processed plate according to the present invention is completed by performing these processes after the filler 68 is filled.

  The obtained processed board is sent to an automatic mounting process, and various electronic components are mounted on the surface of the processed board. After completion of automatic mounting, simply fold the frame part along the V-cut, or scrape off the filler with an appropriate tool (for example, a needle), or an appropriate chemical (for example, in the case of a heat-drying type resin, After the filler is peeled off using a sodium hydroxide aqueous solution or the like, if the frame portion is bent along the V-cut, the product plate temporarily fixed to the frame portion can be easily separated.

The processed plate according to the present invention can be manufactured using a general-purpose V-cut processing device and a screen printing machine as they are, and does not require a special device to maintain the strength of the processed plate. is there.
Further, in the case of manufacturing an irregularly shaped substrate (substrate having a convex portion), when only the V-cut method is used, router processing may be required. Router processing has the disadvantage that the production efficiency is low because the volume of material removal is large. On the other hand, when the pushback method and the V-cut method are used in combination, the router processing with low production efficiency becomes unnecessary by optimizing the shape of the area to be pushed back. For this reason, when the method according to the present invention is used, a processed plate having strength and flatness that can withstand automatic mounting and temporarily fixed with product plates having various shapes can be obtained at extremely low production efficiency and at low cost. Can be manufactured.

Although the embodiments of the present invention have been described in detail above, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the present invention.
For example, when forming a V-cut that communicates with the periphery of the product plate, the V-cut is not limited to being formed on or near the tangent line of the product plate, or on or near the shared straight line portion, You may form toward the outer periphery of a frame part from the arbitrary one points (a corner part is included) on the circumference | surroundings of a product board.

  In FIG. 1, the pushback plate 14 and the V-cut plate 16 are both unit plates integrated through a common straight line portion. However, the pushback plate 14 and the V-cut plate 16 are directly used as product plates. Can also be used. In this case, the second V cuts 20, 20,. Similarly, in FIG. 3, when the first pushback plate 44 is used as a product plate as it is, the V cut 48 on the shared straight line portion of the unit plates 44 a and 44 b may be omitted.

Further, the slit formed in the frame portion is for reducing the warp generated in the processed plate, and is therefore effective for the processed plate in which the product plate is temporarily fixed by the pushback method. You may form in the circumference | surroundings of the processed board to which the product board was temporarily fixed by the cutting method.
Further, the present invention is particularly effective when applied to a metal substrate, but can also be applied to a resin substrate. For example, when warping occurs in the resin substrate, if V-cut processing is performed on this, the depth of the V-cut becomes deeper than a predetermined depth, and the strength of the resin substrate may be reduced. In such a case, if at least a part of the V-cut is filled with a filler, it is possible to suppress breakage of the resin substrate during handling.

The processed board according to the present invention can be used as a mounting board in which a printed circuit board made of a resin substrate or a metal substrate is temporarily fixed by a V-cut method and / or a pushback method.
Moreover, the manufacturing method of the product board which concerns on this invention can be used as a manufacturing method of the printed circuit board which consists of a resin substrate or a metal substrate.

1 (a), FIG. 1 (b), FIG. 1 (c), and FIG. 1 (d) are respectively a plan view of a processed plate according to the first embodiment of the present invention, and B -B 'sectional view, CC' sectional view, and DD 'sectional view. 2 (a), 2 (b), and 2 (c) are a plan view of a processed plate according to a second embodiment of the present invention and a cross-sectional view taken along the line BB ′, respectively. And a sectional view taken along the line CC ′. 3 (a), 3 (b), and 3 (c) are a plan view of a processed plate according to a third embodiment of the present invention, and a cross-sectional view taken along line BB ′, respectively. And a sectional view taken along the line CC ′. It is process drawing which shows the filling method of the filler to V cut.

Explanation of symbols

10 Mounting board (processed board)
12 Frame part 14 Pushback board 14a 1st unit board (product board)
16 V-cut plate 16a Second unit plate (product plate)
18 First V-cut (V-cut)
20 Second V-cut (V-cut)
22 Filler 30 Mounting board (processed board)
32 Frame 34 V-cut board (Product board)
36 V-cut 38 Filler 40 Mounting board (processed board)
42 Frame portion 44 First pushback plates 44a, 44b Unit plate (product plate)
46 Second pushback plate (product plate)
48 V-cut 50 filler

The present invention relates to a processed board , a manufacturing method thereof, and a manufacturing method of a product board, and more particularly, one or more pushes pushed back from a mother board (for example, a printed wiring mother board, a metal board, etc.). A processed plate (for example, a mounting substrate) including a back plate and / or a product plate (for example, a printed circuit board) formed of a V-cut plate temporarily fixed to the frame portion by V-cut, and a manufacturing method thereof . And a method of manufacturing such a product plate.

The problem to be solved by the present invention is a processed board (for example, a mounting board) that can withstand automatic mounting and can be easily separated into individual product boards (for example, printed circuit boards) regardless of the material. And a manufacturing method thereof .
Another problem to be solved by the present invention is to provide a method of manufacturing a product plate that can easily and inexpensively separate the product plate regardless of its material.

In order to solve the above problems, a processed plate according to the present invention includes a frame portion made of a metal material, a product plate made of the metal material temporarily fixed to the frame portion by a pushback method or a V-cut method , and at least the above-described plate One or two or more V-cuts communicating with the periphery of the product plate and communicating with the outer periphery of the frame portion, and a filler filled in at least a part of at least one of the V-cuts. Is the gist.
In this case, the filler preferably contains a resin. Also, it said product plate, either or both of the other products plate to the frame portion or adjacent via the V-cut may be a V-cut plate which is temporarily fixed. Further, the product plate may be a pushback plate that is punched from a mother plate including the frame portion by using the pushback method and is temporarily fixed to the frame portion by being fitted into an original hole.
Moreover, the manufacturing method of the product board which concerns on this invention makes it a summary to fracture | rupture a frame part along V cut with which the processed board which concerns on this invention is equipped, and to separate a product board from a frame part.
Furthermore, the manufacturing method of the processed plate according to the present invention includes a product plate and a mother plate including a frame portion for temporarily fixing the product plate by a pushback method or a V-cut method, and communicates with the periphery of the product plate, and A V-cut forming step of forming one or more V-cuts communicating with the periphery of the frame portion, and a filling step of filling at least a portion of at least one of the V-cuts with a filler. The gist.

Further, in the present embodiment, each pushback plate 14, 14... Is formed by integrating two or more first unit plates 14a, 14a... Via the first shared straight line portions 14b, 14b. . In addition, each V-cut plate 16, 16... Is formed by integrating two or more second unit plates 16a, 16a... Via second shared linear portions 16b, 16b . The first unit plates 14a, 14a ... and the second unit plates 16a, 16a ... are printed circuit boards (product boards) which are final products.
First shared linear portion 14b, 14b ... and the second shared linear portion 16b, 16b ..., respectively, are arranged in a straight line, a 2V cut 20, 20 is formed on or near. Each first unit plate 14a, 14a... And each second unit plate 16a, 16a... Are appropriately formed with pin holes, through holes and the like for mounting electronic components.

The first pushback plate 44 and the second pushback plate 46 are both punched from a printed wiring board (a mounting board before cutting the outer shape) and fitted into the original holes. The periphery of the first pushback plate 44 and the second pushback plate 46 is supported by a frame portion 42, respectively.
The first push back plate 44 exhibits an L-shaped, which two unit plates 44a and 44b are integrated through the shared linear portion 44c, the shared linear portion 44c or in the vicinity thereof, V A cut 48 is formed. In the present embodiment, the two unit plates 44a and 44b and the second pushback plate 46 are printed circuit boards (product boards) as final products. Furthermore, although not shown, the first pushback plate 44 and the second pushback plate 46 are appropriately formed with pin holes, through holes, and the like for mounting electronic components.

The present invention relates to a method of manufacturing a machined plate及beauty products plate, more particularly, the base plate (e.g., a printed circuit mother board, a metal plate or the like.) Pushed-back one or more pushback plate and from / or sheet product comprising a V-cut plate which is temporarily fixed to the frame by V-cut (e.g., a printed circuit board or the like.) machining plate (e.g., a mounting substrate or the like.), and, of product sheets, such as this It relates to a manufacturing method.

The problem to be solved by the present invention is a processed board (for example, a mounting board ) that can withstand automatic mounting and can be easily separated into individual product boards (for example, printed circuit boards) regardless of the material. Is to provide.
Another problem to be solved by the present invention is to provide a method of manufacturing a product plate that can easily and inexpensively separate the product plate regardless of its material.

In order to solve the above problems, a processed plate according to the present invention includes a frame portion made of a metal material, a product plate made of the metal material temporarily fixed to the frame portion by a pushback method or a V-cut method, and at least the above-described plate One or two or more V-cuts communicating with the periphery of the product plate and communicating with the outer periphery of the frame portion, and a filler filled in at least a part of at least one of the V-cuts. Is the gist.
In this case, the filler preferably contains a resin. Further, the product plate may be a V-cut plate temporarily fixed to either one or both of the frame portion and another adjacent product plate via the V-cut. Further, the product plate may be a pushback plate that is punched from a mother plate including the frame portion by using the pushback method and is temporarily fixed to the frame portion by being fitted into an original hole.
A method of manufacturing a product sheet according to the present invention is to break the frame portion along the V-cut provided in machining plate according to the present invention shall be the subject matter that to separate the product plate from the frame portion.

Further, in the present embodiment, each pushback plate 14, 14... Has two or more first unit plates 14 a, 14 a... As a first shared straight portion (a boundary line between the first unit plates 14 a, 14 a). It consists of what was integrated via 14b, 14b .... Each of the V-cut plates 16, 16... Has two or more second unit plates 16a, 16a... Via second shared straight line portions (boundary lines between the second unit plates 16a, 16a) 16b, 16b. And integrated. The first unit plates 14a, 14a ... and the second unit plates 16a, 16a ... are printed circuit boards (product boards) which are final products.
The first shared straight line portions 14b, 14b ... and the second shared straight line portions 16b, 16b ... are arranged on a straight line, and the second V cuts 20, 20 ... are formed on or in the vicinity thereof. Each first unit plate 14a, 14a... And each second unit plate 16a, 16a... Are appropriately formed with pin holes, through holes and the like for mounting electronic components.

The first pushback plate 44 and the second pushback plate 46 are both punched from a printed wiring board (a mounting board before cutting the outer shape) and fitted into the original holes. The periphery of the first pushback plate 44 and the second pushback plate 46 is supported by a frame portion 42, respectively.
The first pushback plate 44 is L-shaped, and the two unit plates 44a and 44b are integrated via a shared straight line portion (border line between the unit plates 44a and 44b) 44c. A V-cut 48 is formed on or near the straight portion 44c. In the present embodiment, the two unit plates 44a and 44b and the second pushback plate 46 are printed circuit boards (product boards) as final products. Furthermore, although not shown, the first pushback plate 44 and the second pushback plate 46 are appropriately formed with pin holes, through holes, and the like for mounting electronic components.

Claims (9)

A frame,
A product plate temporarily fixed to the frame portion;
One or two or more V-cuts communicating with at least the periphery of the product plate and communicating with the outer periphery of the frame portion;
A processed plate comprising a filler filled in at least a part of at least one of the V-cuts.   The processed plate according to claim 1, wherein the filler includes a resin.   The processed plate according to claim 1, wherein the product plate is a V-cut plate temporarily fixed to the frame portion and / or another adjacent product plate via the V-cut.   The said product board is a pushback board which was punched out from the mother board containing the said frame part, and was temporarily fixed by the said frame part by being inserted in the original hole. Processed board. The product plate is
A pushback plate punched from the mother board including the frame portion and temporarily fixed to the frame portion by being fitted into the original hole;
A V-cut plate adjacent to the pushback plate and temporarily fixed to the frame portion via the V-cut;
At least both ends of the pushback plate are supported by the frame portion,
The V-cut is a first V-cut formed on or near a common tangent line of the pushback plate and the frame portion and formed at both ends of the pushback plate. Processed board. The pushback plate is composed of two or more first unit plates integrated through a first shared straight line portion,
The V-cut plate is composed of two or more second unit plates integrated through a second shared straight line portion,
The first shared straight line portion and the second shared straight line portion are aligned on a straight line,
The processed plate according to claim 5, wherein the V-cut is a second V-cut formed on or in the vicinity of the first shared straight line portion and the second shared straight line portion.   The processed plate according to any one of claims 1 to 6, further comprising one or more slits communicating with an outer periphery of the frame portion and not communicating with the product plate.   The processed plate according to any one of claims 1 to 7, wherein the frame portion and the product plate are made of a metal material. The manufacturing method of the product board which fractures | ruptures the said frame part along the said V cut with which the said processed board in any one of Claim 1-8 is equipped, and isolate | separates the said product board from the said frame part.

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