JP5808147B2 - Component mounting method and board - Google Patents

Description

  The present invention relates to a component mounting method and a board.

  A method of mounting a cylindrical electronic component on a mounting position on a substrate has been proposed. For example, in Patent Document 1, a plurality of lands are formed on a substrate corresponding to both sides of the mounting position of an electronic component, dumpling solder is formed on the lands, and an electron is formed on the dumpling solder. A method for placing parts is proposed. Further, for example, Patent Document 2 discloses a method in which a trapezoidal mounting hole is provided on a substrate, a mounting land is provided on the substrate near the bottom of the mounting hole, and a cylindrical electronic component is placed in the mounting hole. Propose.

Japanese Patent Laid-Open No. 07-038245 Japanese Patent Laid-Open No. 08-097521

  Depending on the mounting technology of electronic components disclosed in Patent Documents 1 and 2, the area occupied by the mounted components with respect to the board surface becomes wide. In particular, when a plurality of components are mounted on a substrate, an area corresponding to the number to be mounted is required. Therefore, there is a problem that the area occupied by the components cannot be kept small. Further, when a cylindrical component is mounted on the board surface, it is necessary to prevent positional displacement of the mounted component.

  The present invention is a method for mounting a cylindrical component on a board surface, and provides a component mounting method capable of suppressing the occupied area of the mounting component with respect to the board surface and preventing displacement of the mounting component. Objective.

A component mounting method according to an embodiment of the present invention is a method of mounting a plurality of cylindrical components on a substrate. The component mounting method includes a first step of mounting a cylindrical part on the board surface as first and second vertical parts, and mounting the cylindrical part so that the cylindrical side surface and the board surface are aligned. a lower part and mounted flat on the substrate, mounting the second step of the cylindrical side surface supporting lifting of the lower part, the upper part of the lower part and the upper part of the cylindrical, is brought into contact with the lower part And a third step. Further, in the short-side cross-section of the upper and lower parts mounted on the substrate, a line segment extending perpendicularly to the board surface from the center of the cross-section circle of the lower part, and the cross-section of the lower part A lower stage angle, which is an angle formed by a line connecting the center of the circle and a point supporting the lower part, is a line that extends perpendicularly to the substrate surface from the center of the circle of the cross section of the upper part; The upper part is larger than the upper part angle formed by a line connecting the centers of the circles of the cross-sections of the lower part, and the second step is configured such that the cylindrical side surface of the lower part is the first vertical type. The third step includes a step of supporting the cylindrical side surface of the upper part by making point contact with the second vertical part.

  According to the component mounting method of the present invention, when a plurality of cylindrical components are laid and mounted on a substrate, the occupied area of the mounted component with respect to the substrate surface can be suppressed, and displacement of the mounted component can be prevented. .

2 is a diagram illustrating a configuration example of Example 1. FIG. It is a figure explaining the arrangement position of the cylindrical component mounted in a printed wiring board. It is a figure explaining the position shift prevention effect by the component mounting method of Example 1. FIG. It is a side view of a printed wiring board in a state where all cylindrical parts to be mounted are arranged and dropped into a rectangular hole and mounted. 6 is a diagram illustrating a configuration example of Example 2. FIG. 10 is a diagram illustrating a configuration example of Example 3. FIG. 10 is a diagram illustrating a configuration example of Example 4. FIG.

  FIG. 1 is a diagram illustrating a configuration example of the first embodiment of the present invention. FIG. 1A shows a state in which a plurality of cylindrical parts are mounted on a printed wiring board. FIG. 1B shows a state in which the cylindrical part and the printed wiring board shown in FIG. 1A are viewed obliquely from above. FIG. 1C shows a state in which the printed wiring board before mounting the cylindrical part is viewed obliquely from above.

  The printed wiring board 4 is formed with a first rectangular hole 5 for dropping and mounting the first lower cylindrical part 1 and a second rectangular hole 6 for dropping and mounting the second lower cylindrical part 2. It is a substrate that has been.

  The first rectangular hole 5 is substantially surrounded by the first short substrate end 51, the second short substrate end 52, the first long substrate end 53, and the second long substrate end 54. It is cut out to form a rectangular hole. The lengths of the first longitudinal substrate end 53 and the second longitudinal substrate end 54 are slightly larger than the length of the first lower cylindrical part 1. The lengths of the first short substrate end 51 and the second short substrate end 52 are formed to be slightly smaller than the diameter of the first lower cylindrical part 1.

  The second rectangular hole 6 is substantially surrounded by a third short substrate end 61, a fourth short substrate end 62, a third long substrate end 63, and a fourth long substrate end 64. It is cut out to form a rectangular hole. The second rectangular hole 6 is formed at a position separated substantially in parallel with the first rectangular hole. The lengths of the third longitudinal substrate end 63 and the fourth longitudinal substrate end 64 are slightly larger than the length of the second lower cylindrical part 2. The lengths of the third short substrate end 61 and the second short substrate end 62 are formed to be slightly smaller than the diameter of the second lower cylindrical part 2.

  As shown in FIGS. 1A and 1B, the first lower cylindrical part 1 is mounted on the printed wiring board 4 so as to drop into the first rectangular hole 5. The second lower cylindrical part 2 is mounted on the printed wiring board 4 so as to drop into the second rectangular hole 6. The upper cylindrical part 3 is mounted on the upper parts of the first lower cylindrical part 1 and the second lower cylindrical part 2 with the cylindrical side surface in contact therewith. The first lower cylindrical part 1, the second lower cylindrical part 2, and the upper cylindrical part 3 include cylindrical electronic parts such as an electrolytic capacitor.

  FIG. 2 is a diagram for explaining an arrangement position of the cylindrical component mounted on the printed wiring board. The first lower cylindrical part 1, the second lower cylindrical part 2 and the upper cylindrical part 3 are cylindrical parts having a cylindrical bottom surface. The diameter of each cylindrical bottom is D. A first rectangular hole 5 and a second rectangular hole 6 are formed in the printed wiring board 4 in parallel. In each rectangular hole, the length of the first to fourth short substrate ends is W. The distance between the center of the first rectangular hole 5 and the center of the second rectangular hole 6 is P.

  In the present embodiment, the first rectangular hole 5 and the second rectangular hole 6 are formed in the printed wiring board 4 so that W <D and P> D. The first lower cylindrical part is dropped into the first rectangular hole 5 until the cylindrical side surface is in contact with the first longitudinal substrate end 53 and the second longitudinal substrate end 54. The first lower cylindrical part is mounted by being supported by the first longitudinal substrate end 53 and the second longitudinal substrate end 54. Thereby, the position shift of the first lower cylindrical part is prevented.

  The second lower cylindrical part is dropped into the second rectangular hole 6 until the cylindrical side surface is in contact with the third longitudinal substrate end 63 and the fourth longitudinal substrate end 64. The second lower cylindrical part is mounted by being supported by the third longitudinal substrate end 63 and the fourth longitudinal substrate end 64. Thereby, the position shift of the second lower cylindrical part is prevented.

  The upper cylindrical part 3 is mounted on the upper part of the first lower cylindrical part 1 and the second lower cylindrical part 2 in contact with the cylindrical side surface. The upper cylindrical part 3 is supported and mounted on the cylindrical side surfaces of the first lower cylindrical part 1 and the second lower cylindrical part 2. Thereby, position shift of the upper cylindrical part 3 is prevented.

  In the mounting state shown in FIG. 2, the angle formed by the line segment connecting the center points of the upper cylindrical part 3 and the first lower cylindrical part 1 and the line segment perpendicular to the printed wiring board surface is an angle a. is there. The angle formed by the line segment connecting the contact point between the center point of the first lower cylindrical part 1 and the first longitudinal substrate end 53 and the line segment perpendicular to the printed wiring board surface is an angle b. is there.

In the present embodiment, each cylindrical component is mounted so that the relationship between the corner a and the corner b satisfies the corner a <angle b.
In the mounted state,
Sin (a) = (P / 2) / D
Sin (b) = (W / 2) / (D / 2) = W / D
It is. Therefore, W> P / 2. As a result, a stable mounting state is obtained.

  From the description with reference to FIG. 1 and FIG. 2, the component mounting method of the present embodiment is a method of mounting a cylindrical component on a substrate. In this component mounting method, a cylindrical part is laid and mounted on the printed wiring board 4 so that the cylindrical side surface and the board surface are aligned to form lower parts (lower part cylindrical parts 1 and 2). A step of supporting the cylindrical side surface by line contact. In addition, this component mounting method includes a step of mounting a cylindrical upper part (upper cylindrical part 3) in contact with the lower part on the upper part of the lower part. As shown in FIG. 2, the lower step angle (corner b) is larger than the upper step angle (corner a) in the cross section in the short direction of the upper and lower parts mounted on the substrate. The cross section in the short direction is a cross section when cut in the short direction. The lower stage angle is the angle formed by the line segment that extends perpendicularly to the board surface from the center of the lower part cross section circle and the line that connects the center of the lower part cross section circle and the point that supports the lower part. It is. The upper stage angle is an angle formed by a line segment extending perpendicularly to the substrate surface from the center of the cross-section circle of the upper part and a line segment connecting the centers of the cross-section circles of the upper and lower parts.

  In the step of supporting the cylindrical side surface of the lower part, a part of the lower part is dropped into a rectangular hole (first and second rectangular holes) provided in the printed wiring board 4 and the longitudinal direction of the rectangular hole is reduced. The lower part is supported by line contact at the parallel ends (first to fourth longitudinal substrate ends).

  FIG. 3 is a diagram for explaining the effect of preventing misalignment by the component mounting method according to the first embodiment. FIG. 3A shows a printed wiring board on which cylindrical components are mounted according to the component mounting method of the first embodiment. The arrows in FIGS. 3A and 3B indicate weighted vectors applied to the respective parts in a state where cylindrical parts are mounted on the printed wiring board 4.

  Assume that a weight vector 7 is applied to the upper cylindrical part 3 in a direction perpendicular to the surface of the printed wiring board. The weight vector 7 is decomposed into a weight vector 31 from the center point of the upper cylindrical part 3 toward the contact point with the first lower cylindrical part 1 and a weight vector 32 toward the contact point with the second lower cylindrical part 2. The

  In this embodiment, the angle a is smaller than the angle b. Accordingly, the weight vector 31 is directed from the center point of the first lower cylindrical part 1 toward the contact point with the first longitudinal substrate end portion 53 and the contact point with the second longitudinal substrate end portion 54. It is decomposed into a weight vector 56. The weight vector 32 toward the contact point with the second lower cylindrical part 2 includes the weight vector from the center point of the second lower cylindrical part 2 toward the contact point with the third longitudinal substrate end 63, and the fourth longitudinal direction. It decomposes | disassembles into the weight vector which goes to the contact with the board | substrate edge part 64. FIG. Thereby, the weight vector to the upper cylindrical part is distributed to a plurality of contact points between the lower cylindrical part and the rectangular hole, and acts in a direction in which the lower cylindrical part is brought into close contact with the rectangular hole. As a result, misalignment and the like are prevented, and stable component mounting is possible.

  FIG. 3B shows the weight vector applied to each cylindrical part and the printed wiring board 4 when the angle a> the angle b, contrary to the present embodiment described with reference to FIG. Show. Assume that a weight vector 7 is applied to the upper cylindrical part 3 in the mounting state as shown in FIG. As shown in FIG. 3B, the weight vector 31 includes a weight vector 55 from the center point of the first lower cylindrical part 1 toward the contact point with the first longitudinal substrate end 53, and a second longitudinal length. It is decomposed into a weight vector 57 in the direction opposite to the contact point with the substrate end 54. The weight vector 57 shown in FIG. 3B acts in a direction in which the first lower cylindrical part 1 is moved out of the first rectangular hole 5. Therefore, the mounting state becomes unstable with respect to stress such as weighting and pressing.

  Hereinafter, with reference to FIG. 2 and FIG. 4, the effect of reducing the occupied area by the component mounting method of the present embodiment will be described. As shown in FIG. 2, in the state in which the cylindrical component is mounted on the printed wiring board 4 by the component mounting method of the present embodiment, the component width occupied by each cylindrical component is E = P + D.

FIG. 4 is a side view of the printed wiring board in a state where all the cylindrical parts to be mounted are arranged and dropped into a rectangular hole and mounted. The part width F occupied by the cylindrical parts 1 to 3 shown in FIG. 4 is F = 3 × D.
here,
W <D
W> P / 2
It is. Therefore,
E = P + D <2 × D + D = 3 × D = F.

  From the above, the component width E occupied by each cylindrical component mounted by the component mounting method of this embodiment is smaller than the component width F in the mounted state shown in FIG. As a result, according to the component mounting method of the present embodiment, the area occupied by the cylindrical component can be kept small.

For example, a case where the diameter of the cylindrical bottom surface of the cylindrical part is D = 10 mm and the component mounting method of this embodiment is applied will be described. The length of the short substrate end is W = 8 mm, and the distance between the centers of the rectangular holes is P = 12 mm. Thereby, the condition of W <D and P> D and W> P / 2 is satisfied. Further, since the angle a is about 37 degrees and the angle b is about 53 degrees, the condition of angle a <angle b is also satisfied. At this time, h in FIG. 2 is 16 mm, H is 18 mm, and E is 22 mm. When the length of the bottom surface of the cylinder is L = 40 mm, the occupied area is 40 mm (L) × 22 mm (E) = 880 mm ² .

On the other hand, when the form of the present embodiment is not applied and three cylindrical parts are mounted side by side on the substrate, the occupied area is 40 mm (L) × 30 mm (3 × D) = 1200 mm ² . Therefore, it can be seen that the area occupied by the cylindrical part on the printed wiring board can be reduced by applying the present embodiment.

  According to the component mounting method of the first embodiment described above, the area occupied by the cylindrical component can be kept small by mounting the cylindrical component in multiple directions in the height direction from the printed wiring board surface. In addition, according to the component mounting method of the first embodiment, it is difficult for the cylindrical component to be taken out from the supporting rectangular hole, and positional displacement and the like are prevented. As a result, stable component mounting is possible.

  FIG. 5 is a diagram illustrating a configuration example of the second embodiment of the present invention. FIG. 5A shows a state where a plurality of cylindrical parts are mounted on a printed wiring board. FIG. 5B shows a state in which the cylindrical part and the printed wiring board shown in FIG. 5A are viewed obliquely from above. In addition, the arrow in FIG. 5A indicates a weight vector applied to each cylindrical part and the printed wiring board when a weight is applied to the upper cylindrical part from above.

  On the printed wiring board 4, a first vertical cylindrical component 10, a second vertical cylindrical component 11, a third vertical cylindrical component 21, and a fourth vertical cylindrical component 22 are mounted. In the present embodiment, unlike the first embodiment, the second lower cylindrical component 2 (FIG. 1) is not mounted on the printed wiring board 4. In each of the first to fourth vertical cylindrical parts, the terminals on the bottom surface are soldered to the substrate, and the positional deviation and the inclination with respect to the lateral load are prevented from being mounted.

  The first lower cylindrical part 1 is mounted with a cylindrical side surface in contact with the first vertical cylindrical part 10, the second vertical cylindrical part 11, and the printed wiring board 4, thereby preventing misalignment and the like. Further, the upper cylindrical part 3 is mounted in such a manner that displacement of the upper cylindrical part 3 is prevented by contacting a cylindrical side surface with the first lower cylindrical part 1, the first vertical cylindrical part 21, and the second vertical cylindrical part 22. ing.

  As shown in FIG. 5A, the angle formed by the line connecting the center point of the upper cylindrical part 3 and the first lower cylindrical part 1 and the line perpendicular to the printed wiring board surface is an angle. a. The angle formed by the line segment connecting the contact point between the center point of the first lower cylindrical part 1 and the first vertical cylindrical part 10 and the line segment perpendicular to the printed wiring board surface is an angle b. It is. Also in the present embodiment, each cylindrical component is mounted so that the relationship between the corner a and the corner b satisfies the corner a <angle b.

  That is, in the component mounting method of the second embodiment, a cylindrical component is mounted on the printed wiring board 4 so that the cylindrical side surface and the substrate surface are aligned to form a lower component (lower component cylindrical component 1). A step of supporting the cylindrical side surface of the lower part by point contact. In addition, this component mounting method includes a step of mounting a cylindrical upper part (upper cylindrical part 3) in contact with the lower part on the upper part of the lower part. Then, as shown in FIG. 5A, the lower step angle (corner b) is larger than the upper step angle (corner a) in the cross section in the short direction of the upper and lower parts mounted on the substrate.

  In addition, the step of supporting the cylindrical side surface of the lower part is a point contact with the cylindrical parts (first and second vertical cylindrical parts) mounted with the cylindrical side surface of the lower part standing on the printed wiring board 4. And supporting it. In the process of mounting the upper part, the cylindrical side surface of the upper part is supported by making point contact with cylindrical parts (first and second vertical cylindrical parts) mounted on the printed circuit board 4 while standing. Process.

  As shown in FIG. 5B, it is assumed that a weight vector 7 is applied to the upper cylindrical part 3 in a direction perpendicular to the printed wiring board surface. The weight vector 7 includes a weight vector 31 from the center point of the upper cylindrical part 3 toward the contact point with the first lower cylindrical part 1 and a weight vector 32 toward the contact point with the first and second vertical cylindrical parts 22. And decomposed.

  In this embodiment, the cylindrical part is mounted so that the angle a <angle b. Accordingly, the weight vector 31 is a weight vector 55 from the center point of the first lower cylindrical part 1 toward the contact point with the first and second vertical cylindrical parts and a weight vector toward the contact point with the printed circuit board 4. 56. Thereby, a force acts in the direction in which the first lower cylindrical part 1 is brought into close contact with the plurality of contacts.

  According to the component mounting method of the second embodiment, a plurality of cylindrical components are mounted in a multiple manner in the height direction from the surface of the printed wiring board, and the occupied area can be kept small. Furthermore, even if a weight vector is applied, it is difficult for the cylindrical part to float from the printed wiring board that is supported or to get over other cylindrical parts, and positional displacement is prevented. As a result, stable component mounting is possible.

  FIG. 6 is a diagram illustrating a configuration example of the third embodiment of the present invention. In Example 3, the diameter of the upper cylindrical part 30 is larger than the diameters of the first and second lower cylindrical parts 1. Other configurations are the same as those of the first embodiment. That is, the cylindrical part is mounted so that the angle a <angle b.

  As shown in FIG. 6, it is assumed that a weight vector 7 is added to the upper cylindrical part 30. The weight vector 7 is decomposed into a weight vector 31 directed from the center point of the upper cylindrical part 30 to the contact point with the first lower cylindrical part 1 and a weight vector 32 directed toward the contact point with the second lower cylindrical part 2. The

  In this embodiment, the angle a is smaller than the angle b. Accordingly, the weight vector 31 is directed from the center point of the first lower cylindrical part 1 toward the contact point with the first longitudinal substrate end portion 53 and the contact point with the second longitudinal substrate end portion 54. It is decomposed into a weight vector 56. Thereby, the weight vector to the upper cylindrical part is distributed to a plurality of contact points between the lower cylindrical part and the rectangular hole, and acts in a direction in which the lower cylindrical part is brought into close contact with the rectangular hole. As a result, misalignment and the like are prevented, and stable component mounting is possible. In the above-described second embodiment and later-described fourth embodiment, similarly to the third embodiment, an upper cylindrical component having a diameter larger than the diameter of the lower cylindrical component may be mounted.

  According to the component mounting method of the third embodiment, by occupying multiple cylindrical components in the height direction from the printed wiring board surface, the area occupied by the cylindrical components can be kept small. In addition, according to the component mounting method of the third embodiment, it is difficult for the cylindrical-shaped component to be taken out from the supporting rectangular hole, and positional deviation and the like are prevented. As a result, stable component mounting is possible.

  FIG. 7 is a diagram illustrating a configuration example of the fourth embodiment of the present invention. A first curved concave portion 58 and a second curved concave portion 68 are formed on the printed wiring board 4. Each cylindrical component is mounted so that the angle a <angle b.

  The first curved recess 58 is formed so as to be in surface contact along the cylindrical side surface of the first lower cylindrical part 1 in the range from the first longitudinal substrate end 53 to the second longitudinal substrate end 54. . The second curved concave portion 68 is formed so as to be in surface contact along the cylindrical side surface of the second lower cylindrical part 2 in the range from the third longitudinal substrate end 63 to the fourth longitudinal substrate end 64. .

  That is, in the component mounting method of the present embodiment, the cylindrical component is mounted on the printed wiring board 4 so that the cylindrical side surface and the substrate surface are aligned to form lower components (lower component cylindrical components 1 and 2). And a step of supporting the cylindrical side surface of the lower part by surface contact. In addition, this component mounting method includes a step of mounting a cylindrical upper part (upper cylindrical part 3) in contact with the lower part on the upper part of the lower part. As shown in FIG. 7, the lower step angle (corner b) is larger than the upper step angle (corner a) in the short-side cross-sections of the upper and lower parts mounted on the substrate.

  In the step of supporting the cylindrical side surface of the lower part, a part of the lower part is dropped into the curved concave portions (58, 68) provided in the printed wiring board 4, and the lower part is brought into surface contact with the curved surface of the curved concave portion. To support.

  As shown in FIG. 7, it is assumed that a weight vector 7 is applied to the upper cylindrical part 3 in a direction perpendicular to the printed wiring board surface. The weight vector 7 includes a weight vector 31 from the center point of the upper cylindrical part 3 toward the contact point with the first lower cylindrical part 1 and a weight vector 32 toward the contact point with the first and second vertical cylindrical parts 22. And decomposed.

  Since the angle a <angle b, the weight vector 31 can be decomposed in the first longitudinal substrate end portion 53 direction and the second longitudinal substrate end portion 54 direction, and is distributed on the contact surface by the first curved concave portion 58. Weighted. Further, the weight vector 32 can be decomposed in the direction of the third longitudinal substrate end 63 and the direction of the fourth longitudinal substrate end 64, and is distributed and applied to the contact surface by the first curved concave portion 68.

  According to the component mounting method of the fourth embodiment, the area occupied by the cylindrical component can be reduced by mounting the cylindrical component in a multiple direction in the height direction from the printed wiring board surface. Further, according to the component mounting method of the fourth embodiment, it is difficult for the cylindrical-shaped component to come out from the curved concave portion that is supported, and positional displacement is prevented. As a result, stable component mounting is possible.

DESCRIPTION OF SYMBOLS 1 First lower cylindrical part 2 Second lower cylindrical part 3 Upper cylindrical part 4 Printed wiring board 5 First rectangular hole 6 Second rectangular hole

Claims (2)

A method of mounting a plurality of cylindrical parts on a substrate,
A first step of mounting two cylindrical parts on the board surface as first and second vertical parts; and
Parts of cylindrical shape, a second step of the lower part and mounted flat on the substrate along the cylindrical side surface and the substrate surface, to supporting lifting the cylindrical side surface of the lower part,
A third step of mounting a cylindrical upper part in contact with the lower part on the upper part of the lower part; and
In the short-side cross-section of the upper and lower parts mounted on the substrate, a line segment extending perpendicularly to the board surface from the center of the cross-section circle of the lower-stage part, and a cross-section circle of the lower-stage part A lower stage angle, which is an angle formed by a line connecting a center and a point supporting the lower part, is a line segment extending perpendicularly to the substrate surface from the center of a circle of a cross section of the upper part, and the upper stage Larger than the upper stage angle, which is the angle formed by the line segment connecting the centers of the circle of the cross section of the part and the lower part,
The second step includes a step of supporting the cylindrical side surface of the lower part by making point contact with the first vertical part,
The component mounting method according to claim 3, wherein the third step includes a step of supporting the cylindrical side surface of the upper part by making point contact with the second vertical part. A board on which a plurality of cylindrical parts are mounted,
In the mounted state of the cylindrical part,
Two cylindrical components mounted on the substrate surface as first and second vertical components;
A cylindrical lower part mounted on the substrate such that the cylindrical side surface and the substrate surface are laid on the substrate,
A cylindrical upper part mounted in contact with the upper part of the lower part,
Cylindrical side surface of the lower part is supported by touch Tense' said first vertical part,
In a short-side cross section of the upper and lower parts mounted on the substrate, a line segment extending perpendicularly to the substrate surface from the center of the cross section circle of the lower part, and A lower stage angle, which is an angle formed by a line connecting a center and a point supporting the lower part, is a line segment extending perpendicularly to the substrate surface from the center of a circle of a cross section of the upper part, and the upper stage Larger than the upper stage angle, which is the angle formed by the line segment connecting the centers of the circle of the cross section of the part and the lower part,
The board | substrate characterized by the cylindrical side surface of the said upper stage component being supported by the said 2nd vertical part by point contact.

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