The present invention relates to a chip resistor, a mount structure of a chip resistor and a method for manufacturing a chip resistor.
A conventionally known chip resistor (surface mount resistor) includes two leads and a central resistor portion (see Patent Document 1, for example). The central resistor portion is sandwiched between the two leads and bonded to the leads. This type of chip resistor is manufactured by using a plurality of reels. Specifically, a strip of a resistive material is wound around one of the reels, whereas a strip of an electrically conductive material is wound around each of other two reels. The strips are paid out from the reels while rotating the reels, and bonded together in such a manner that the strip of the resistive material is sandwiched between the two strips of an electrically conductive material.
In the technique disclosed in the above-identified document, a strip of a resistive material and a strip of an electrically-conductive material are bonded together by electron beam welding. Electron beam welding is performed in a vacuum atmosphere. Thus, to perform electron beam welding, after strips are placed in a vacuum chamber, the chamber needs to be evacuated. Placing each strip in a vacuum chamber and evacuating the chamber are troublesome. Moreover, after the strips are bonded together, the interior of the vacuum chamber needs to be returned to an atmospheric pressure, which is also troublesome. In this way, the conventional method of bonding strips by electron beam welding is not efficient.
Patent Document 1: Japanese Patent No. 3321724
The present invention has been conceived under the circumstances described above. It is therefore an object of the present invention to provide a chip resistor suitable for enhancing manufacturing efficiency.
According to a first aspect of the present invention, there is provided a chip resistor comprising a first electrode, a second electrode spaced apart from the first electrode in a first direction, a resistor portion bonded to the first electrode and the second electrode, a first intermediate layer connected to the first electrode and the resistor portion, a second intermediate layer connected to the second electrode and the resistor portion, and a coating film covering the first electrode. The coating film is made of a material having a higher absorptance of a laser beam of a predetermined wavelength than that of a material forming the first electrode, and the first intermediate layer contains at least the material forming the coating film.
Preferably, the coating film is made of Sn or solder.
Preferably, the resistor portion extends along a plane spreading in the first direction and a second direction crossing the first direction. The first electrode includes a first principal surface facing one side in the thickness direction of the resistor portion. The coating film includes a first-principal-surface coating portion covering the first principal surface. The first-principal-surface coating portion covers the first principal surface over a region from an end closer to the second electrode in the first direction to an end opposite in the first direction from the end closer to the second electrode.
Preferably, the first electrode includes a second principal surface facing away from the first principal surface. The coating film includes a second-principal-surface coating portion covering the second principal surface.
Preferably, the second-principal-surface coating portion covers the second principal surface over a region from an end closer to the second electrode in the first direction to an end opposite in the first direction from the end closer to the second electrode.
Preferably, the second-principal-surface coating portion is made of the same material as the material forming the first-principal-surface coating portion.
Preferably, the first electrode includes a first side surface facing in the second direction, and the first side surface is exposed from the coating film.
Preferably, the first side surface includes a line-trace formed surface formed with a line trace, and a breakage-trace formed surface connected to the line-trace formed surface and formed with a breakage trace.
Preferably, the first electrode includes a second side surface and a curved surface connected to the first side surface and the second side surface. The second side surface faces in a direction away from the resistor portion in the first direction. The second side surface and the curved surface are exposed from the coating film.
Preferably, the first electrode includes a second side surface. The second side surface faces in a direction away from the resistor portion in the first direction and is covered by the coating film.
Preferably, the resistor portion is sandwiched between the first electrode and the second electrode.
Preferably, the first intermediate layer includes a wide portion and a narrow portion. The wide portion and the narrow portion are exposed in opposite directions from each other.
Preferably, the first intermediate layer includes a wide portion and a narrow portion that is smaller than the wide portion in dimension in the first direction. The wide portion and the narrow portion are exposed in opposite directions from each other.
Preferably, the first electrode includes a plate-like portion extending along the first direction and a second direction crossing the first direction, and an inclined portion inclined with respect to the plate-like portion and closer to the resistor portion than the plate-like portion is.
Preferably, the first electrode and the second electrode are positioned on a same side of the resistor portion.
Preferably, the resistor portion is smaller in thickness than the first electrode.
Preferably, the chip resistor further comprises oxide existing in the first intermediate layer, and the oxide is oxide of a material forming the coating film.
According to a second aspect of the present invention, there is provided a mount structure of a chip resistor. The mount structure comprises the chip resistor provided according to the first aspect of the present invention, a mount board, and a solder layer provided between the mount board and the chip resistor.
According to a third aspect of the present invention, there is provided a chip resistor manufacturing method comprising the steps of preparing an electrically conductive member made of an electrically conductive material and a resistive member made of a resistive material, forming a coating film to cover the electrically conductive member, and bonding the electrically conductive member and the resistive member to each other by application of a laser beam of a predetermined wavelength after the step of forming the coating film. The coating film is formed of a material having a higher absorptance of the laser beam of the predetermined wavelength than that of the electrically conductive material. The bonding step comprises applying the laser beam to the coating film.
Preferably, the coating film is made of Sn or solder.
Preferably, the step of forming the coating film comprises plating.
Preferably, the preparation step comprises preparing a plurality of conductive elongated boards as the electrically conductive member. The method further comprises the step of arranging the conductive elongated boards side by side in the width direction crossing the longitudinal direction of one of the conductive elongated boards before the bonding step. The bonding step comprises bonding the resistive member to the conductive elongated boards to provide a resistor aggregate after the step of arranging.
Preferably, the method further comprises the step of dividing the resistor aggregate by punching to provide a chip resistor including two electrodes and a resistor portion bonded to the two electrodes.
Other features and advantages of the present invention will become more apparent from detailed description given below with reference to the accompanying drawings.
Embodiments of the present invention are described below with reference to the accompanying drawings.
The chip resistor mount structure 800 shown in these figures includes a chip resistor 101, a mount board 801 and a solder layer 802.
For instance, the mount board 801 is a printed circuit board. For instance, the mount board 801 includes an insulating substrate and a pattern electrode (not shown) formed on the insulating substrate. The chip resistor 101 is mounted on the mount board 801. A solder layer 802 is provided between the chip resistor 101 and the mount board 801. The solder layer 802 bonds the chip resistor 101 and the mount board 801 to each other.
The chip resistor 101 includes a first electrode 1, a second electrode 2, a resistor portion 3, a first intermediate layer 4, a second intermediate layer 5, a coating film 61, a coating film 62, oxides 691 (not shown in
The first electrode 1 shown in
The plate-like portion 181 shown in
The first electrode 1 includes a principal surface 11 (second principal surface), a principal surface 12 (first principal surface), two side surfaces 13 (first side surfaces), a side surface 14 (second side surface) and two curved surfaces 15.
The principal surface 11 faces in the direction Z1 (one side in the thickness direction of the resistor portion 3). The principal surface 12 faces in the direction Z2 (i.e., faces away from the principal surface 11). The side surfaces 13, 14 and the curved surface 15 face in a direction perpendicular to the direction z. Specifically, the side surfaces 13 face in the direction Y and the side surface 14 faces in the direction X. The curved surfaces 15 are connected to the side surfaces 13 and the side surface 14.
As shown in
As shown in
As shown in
The second electrode 2, which is shown in
The plate-like portion 281, which is shown in
The second electrode 2 includes a principal surface 21, a principal surface 22, two side surfaces 23, a side surface 24 and two curved surfaces 25. The second electrode 2 is spaced apart from the first electrode 1 in the direction X (first direction).
The principal surface 21 faces in the direction Z1 (one side in the thickness direction of the resistor portion 3). The principal surface 22 faces in the direction Z2 (i.e., faces away from the principal surface 11). The side surfaces 23, 24 and the curved surface 25 face in a direction perpendicular to the direction Z. Specifically, the side surfaces 23 face in the direction Y and the side surface 24 faces in the direction X. The curved surfaces 25 are connected to the side surfaces 23 and the side surface 24.
As shown in
As shown in
As shown in
The resistor portion 3, which is shown in
In this embodiment, the inclined portion 182 is closer to the resistor portion 3 than the plate-like portion 181 is. Similarly, the inclined portion 282 is closer to the resistor portion 3 than the plate-like portion 281 is.
The resistor portion 3 includes a resistor portion front surface 31, a resistor portion reverse surface 32 and two resistor portion side surfaces 33.
The resistor portion front surface 31 faces in the same direction as the principal surface 11 or the principal surface 21 (i.e., the direction Z1). The resistor portion reverse surface 32 faces in the opposite direction from the resistor portion front surface 31. The resistor portion reverse surface 32 faces in the same direction as the principal surface 12 or the principal surface 22 (i.e., the direction Z2). At least part of the principal surface 12 and at least part of the principal surface 22 are deviated from the resistor portion reverse surface 32 toward the side to which the resistor portion reverse surface 32 faces (i.e., the direction Z2).
Each of the resistor portion side surfaces 33, which are shown in e.g.
As shown in
The first intermediate layer 4 includes a wide portion 43 and a narrow portion 44. The wide portion 43 is exposed to the direction Z2. The narrow portion 44 is on the direction Z1 side of the wide portion 43. The dimension of the narrow portion 44 in the direction X is smaller than the dimension of the wide portion 43 in the direction X. That is, the width of the wide portion 43 is larger than that of the narrow portion 44. The width of the first intermediate layer 4 refers to the dimension in the direction in which the portion of the first electrode 1 which is in contact with the first intermediate layer 4 and the portion of the resistor portion 3 which is in contact with the first intermediate layer 4 are spaced apart from each other. For instance, the dimension of the wide portion 43 in the direction X is 1-1.5 mm, whereas the dimension of the narrow portion 44 in the direction X is 0.5-1 mm. The wide portion 43 may have burr (not shown) on the surface. Unlike this embodiment, the first intermediate layer 4 may be formed with a recess 49, as shown in
As shown in
The second intermediate layer 5 includes a wide portion 53 and a narrow portion 54. The wide portion 53 is exposed to the direction Z2. The narrow portion 54 is on the direction Z1 side of the wide portion 53. The dimension of the narrow portion 54 in the direction X is smaller than the dimension of the wide portion 53 in the direction X. That is, the width of the wide portion 53 is larger than that of the narrow portion 54. The width of the second intermediate layer 5 refers to the dimension in the direction in which the portion of the second electrode 2 which is in contact with the second intermediate layer 5 and the portion of the resistor portion 3 which is in contact with the second intermediate layer 5 are spaced apart from each other. For instance, the dimension of the wide portion 53 in the direction X is 1-1.5 mm, whereas the dimension of the narrow portion 54 in the direction X is 0.5-1 mm. The wide portion 53 may have burr (not shown) on the surface. Unlike this embodiment, the second intermediate layer 5 may be formed with a recess 59, as shown in
The coating film 61 covers the first electrode 1. The material forming the coating film 61 has a higher absorptance of a laser beam of a wavelength of λ1 than that of the material forming the first electrode 1. For instance, the wavelength λ1 is 1.03-1.10 μm and 1.05 μm in this embodiment.
Referring to
The coating film 61 includes a principal surface coating portion 611 (second-principal-surface coating portion) and a principal surface coating portion 612 (first-principal-surface coating portion). For instance, the thickness of the coating film 61 is about 5 μm.
The principal surface coating portion 611 covers the principal surface 11. In this embodiment, the principal surface coating portion 611 covers the entirety of the principal surface 11. As shown in
The principal surface coating portion 612 covers the principal surface 12. In this embodiment, the principal surface coating portion 612 covers the entirety of the principal surface 12. As shown in
The principal surface coating portion 612 is made of the same material as that of the principal surface coating portion 611, because the principal surface coating portion 612 and the principal surface coating portion 611 are formed simultaneously. When the principal surface coating portion 611 and the principal surface coating portion 612 are not to be formed simultaneously, different materials may be used for the principal surface coating portion 611 and the principal surface coating portion 612. As shown in
In this embodiment, the coating film 61 does not cover the side surfaces 13 or the side surface 14. Thus, all of the side surfaces 13 and the side surface 14 are exposed from the coating film 61.
The coating film 62 covers the second electrode 2. The material forming the coating film 62 has a higher absorptance of a laser beam of the above-described wavelength of λ1 than that of the material forming the second electrode 2.
Referring to
As shown in
The principal surface coating portion 621 covers the principal surface 21. In this embodiment, the principal surface coating portion 621 covers the entirety of the principal surface 21. As shown in
The principal surface coating portion 622 covers the principal surface 22. In this embodiment, the principal surface coating portion 622 covers the entirety of the principal surface 22. As shown in
The principal surface coating portion 622 is made of the same material as that of the principal surface coating portion 621, because the principal surface coating portion 622 and the principal surface coating portion 621 are formed simultaneously. As shown in
In this embodiment, the coating film 62 does not cover the side surfaces 23 or the side surface 24. Thus, all of the side surfaces 23 and the side surface 24 are exposed from the coating film 62.
As shown in
As shown in
A method for manufacturing the chip resistor 101 is described below.
First, as shown in
Then, as shown in
Similarly, as shown in
Then, as shown in
Laser is used to bond the conductive elongated boards 711 and the resistive member 702. For instance, as shown in
Since laser is used to bond the electrically conductive member 701 and the resistive member 702, the bonding is performed not in vacuum but in the air, which contains a lot of oxygen. Thus, when the coating film 61, the first electrode 1 or the resistor portion 3 melts due to the application of welding laser beams 881 (or before or after the melting), oxides of the materials forming the coating film 61, the first electrode 1 or the resistor portion 3 are formed. The oxides are the above-described oxides 691. The oxides 692 are formed in the same way.
Then, as shown in
As shown in
The advantages of this embodiment are described below.
In the case where the electrically conductive member 701 and the resistive member 702 are to be bonded to each other by using an electron beam, the electrically conductive member 701 and the resistive member 702 need to be placed in a vacuum chamber. In this embodiment, the electrically conductive member 701 and the resistive member 702 are bonded to each other by using welding laser beams 881. Laser beam welding can be performed at an atmospheric pressure and does not need to be performed in vacuum. Thus, welding can be performed without the need for putting the electrically conductive member 701 and the resistive member 702 in a vacuum chamber or evacuating the vacuum chamber. In this way, the method according to the present invention, which uses welding laser beams 881, can omit troublesome works related to welding in vacuum. Thus, the method according to this embodiment is suitable for enhancing the manufacturing efficiency of the chip resistor 101.
In this embodiment, the material forming the coating film 6 has a higher absorptance of a laser beam of the above-described wavelength of λ1 than that of the material forming the electrically conductive member 701. In the step of bonding the electrically conductive member 701 and the resistive member 702, the welding laser beams 881 having the wavelength λ1 is applied to the coating film 6. In this arrangement, when the welding laser beams 881 are applied to the coating film 6, a large amount of heat is generated at the coating film 6. Part of the heat generated at the coating film 6 is used to melt the coating film 6. Meanwhile, part of the heat generated at the coating film 6 is conducted to the electrically conductive member 701. The heat conducted from the coating film 6 to the electrically conductive member 701 is used to melt the electrically conductive member 701. Thus, the electrically conductive member 701 starts to melt quickly, so that the time taken for the bonding of the electrically conductive member 701 and the resistive member 702 shortens. Alternatively, instead of shortening the time taken for the bonding of the electrically conductive member 701 and the resistive member 702, the energy of the welding laser beams 881 can be lowered. Alternatively, the time taken for the bonding of the electrically conductive member 701 and the resistive member 702 can be shortened, while the energy of the welding laser 881 is lowered. Thus, the method according to this embodiment is suitable for enhancing the manufacturing efficiency of the chip resistor 101.
In this embodiment, the coating film 61 and the coating film 62 are made of Sn or solder. The coating film 61 includes the principal surface coating portion 612. The principal surface coating portion 612 covers the end of the principal surface 12 which is on the opposite side from the second electrode 2 in the direction X. Both of Sn and solder have high solder wettability. Thus, the principal surface coating portion 612 and the solder layer 802 are strongly bonded to each other, so that the chip resistor 101 is strongly bonded to the mount board 801. Similarly, the coating film 62 includes the principal surface coating portion 622. The principal surface coating portion 622 covers the end of the principal surface 22 which is on the opposite side from the first electrode 1 in the direction X. Thus, the principal surface coating portion 622 and the solder layer 802 are strongly bonded to each other, so that the principal surface coating portion 622 is strongly bonded to the mount board 801.
In this embodiment, the coating film 61 includes the principal surface coating portion 611. The principal surface coating portion 611 covers the principal surface 11. This arrangement prevents the principal surface 11 from oxidizing or changing in color. Also, the coating film 62 covers the principal surface coating portion 621. The principal surface coating portion 621 covers the principal surface 21. This arrangement prevents the principal surface 21 from oxidizing or changing in color.
According to the embodiment, the resistor aggregate 703 is formed by bonding the resistive member 702 to at least three conductive elongated boards 711. With this arrangement, the number of chip resistors 101 obtained per unit length in the direction Y shown in
Since the chip resistor 101 is manufactured by punching, the dimensional accuracy of the chip resistor 101 as viewed in plan is determined by the dimensional accuracy of the punching dies 831, 832. Accordingly, the dimensional accuracy of the resistor portion 3 of the chip resistor 101 in the direction Y is also determined by the dimensional accuracy of the punching dies 831, 832. According to the method of this embodiment, by selecting punching dies 831, 832 of a desired dimensional accuracy before punching the resistor aggregate 703, the dimensional error in the direction Y of the resistor portions 3 is reduced as compared with the conventional method of successively cutting the strips. When the dimensional error in the direction Y of the resistor portions 3 is reduced, a larger number of resistor portions 3 having a desired resistance are obtained, whereby a larger number of chip resistors 101 having a desired resistance are obtained. When the chip resistor 101 has a desired resistance, the trimming process for adjusting the resistance of the chip resistor 101 does not need to be performed. In this way, the number of chip resistors 101 which require trimming process reduces. This leads to enhancement of the manufacturing efficiency of the chip resistor 101.
In this embodiment, a lead frame is used as the electrically conductive member 701, and a resistive frame is used as the resistive member 702. Thus, it is not necessary to individually hold a plurality of conductive elongated boards 711 or a plurality of resistive elongated boards 721, which facilitates handling.
Unlike the conventional method for manufacturing a chip resistor, this embodiment does not use a reel. Thus, the work of winding a strip of a resistive material or an electrically conductive material around a reel is not necessary. Thus, the use of a large apparatus for winding a strip around a reel is also unnecessary. Since pulling the strip out of the reel is not necessary, the use of a large apparatus for pulling the strip out of the reel is also unnecessary.
When a reel is used to manufacture a chip resistor, the entire production line is stopped if a trouble happens at some point of a strip. Since this embodiment does not use a reel, such a problem does not occur.
In this embodiment, welding laser beams 881 are applied along the direction Z1. According to this arrangement, the conductive elongated board 711 and the resistive elongated board 721 are more likely to absorb the energy of the high energy beams on the direction Z2 side and hence relatively easily melt on this side. As a result, the wide portion 43 exposed in the direction Z2 is formed in the first intermediate layer 4 of the chip resistor 101. Burrs (not shown) may be formed on the surface of the wide portion 43. In this embodiment, each of the conductive elongated board 711 is bent so that the portion of the first electrode 1 or the second electrode 2 which is close to the resistor portion 3 is deviated toward the direction Z1 side from the portion of the first electrode 1 or the second electrode 2 which is distant from the resistor portion 3. According to this arrangement, even when burrs are formed on the surface of the wide portion 43, the burrs are in the recessed portion of the chip resistor 101 and not on the direction z1 side of the chip resistor 101. Thus, when the chip resistor 101 is held by a holder (not shown) for movement, the holder does not come into contact with the burrs. This allows the chip resistor 101 to be moved stably.
Variations of the foregoing embodiment and other embodiments are described below. In the description given below, the elements that are identical or similar to those of the foregoing embodiments are designated by the same reference signs as those used for the foregoing embodiment, and the explanation is omitted appropriately.
<The First Variation of the First Embodiment>
The chip resistor 102 of this variation includes a first electrode 1, a second electrode 2, a resistor portion 3, a first intermediate layer, a second intermediate layer 5, a coating film 61, a coating film 62, oxides 691 (not shown in this variation, see
The first electrode 1 includes a principal surface 11 (second principal surface), a principal surface 12 (first principal surface), two side surfaces 13 (first side surfaces) and a side surface 14 (second side surface), but does not include a curved surface 15. The first electrode 1 of this variation is the same as that of the above-described chip resistor 101 except that the first electrode 1 of this variation does not include a curved surfaces 15 and except the structure of the side surface 14, which is described later.
The side surface 14 is covered by the coating film 61. Unlike the foregoing embodiment, the side surface 14 of this variation does not include the line-trace formed surface 141 or the breakage-trace formed surface 142. The side surface 14 is flat.
The second electrode 2 includes a principal surface 21, a principal surface 22, two side surfaces 23 and a side surface 24 but does not include a curved surface 25. The second electrode 2 of this variation is the same as that of the above-described chip resistor 101 except that the second electrode 2 of this variation does not include a curved surface 25 and except the structure of the side surface 24, which is described later.
The side surface 24 is covered by the coating film 62. Unlike the foregoing embodiment, the side surface 24 of this variation does not include the line-trace formed surface 241 or the breakage-trace formed surface 242. The side surface 24 is flat.
The coating film 61 has the same structure as that of the coating film 61 of the chip resistor 101 of the foregoing embodiment except that the coating film of this variation further includes a side surface coating portion 613. The side surface coating portion 613 covers the side surface 14. The side surface coating portion 613 is connected to both of the principal surface coating portion 611 and the principal surface coating portion 612. As shown in
The coating film 62 has the same structure as that of the coating film 62 of the chip resistor 101 of the foregoing embodiment except that the coating film of this variation further includes a side surface coating portion 623. The side surface coating portion 623 covers the side surface 24. The side surface coating portion 623 is connected to both of the principal surface coating portion 621 and the principal surface coating portion 622.
According to this variation, the same advantages as those of the chip resistor 101 are obtained.
In the chip resistor 102, the coating film 61 includes the side surface coating portion 613. The side surface coating portion 613 is made of a material having high solder wettability. Thus, the side surface coating portion 613 and the solder layer 802 are strongly bonded to each other, so that the chip resistor 102 is strongly bonded to the mount board 801. In the chip resistor 102, the coating film 62 includes the side surface coating portion 623. The side surface coating portion 623 is made of a material having high solder wettability. Thus, the principal surface coating portion 623 and the solder layer 802 are strongly bonded to each other, so that the chip resistor 102 is strongly bonded to the mount board 801.
<Another Variation of the First Embodiment>
The welding laser beams 881 (see
The chip resistor 104 shown in these figures includes a first electrode 1, a second electrode 2, a resistor portion 3, a first intermediate layer 4, a second intermediate layer 5, a coating film 61, a coating film 62, oxides 691 (not shown in this embodiment, see
The first electrode 1, the second electrode 2, the first intermediate layer 4, the second intermediate layer 5, the coating film 61 and the coating film 62 of this variation are the same as those of the above-described chip resistor 101 except the following points.
The thickness of the first electrode 1 and the second electrode 2 (dimension in the direction Z) is larger than the thickness of the resistor portion 3 (dimension in the direction Z). The first electrode 1 and the second electrode 2 each is in the form of a flat plate extending along the X-Y plane and does not include an inclined portion.
The first electrode 1 has an inner side surface 16, and the second electrode 2 has an inner side surface 26. The inner side surface 16 faces toward the second electrode 2, whereas the inner side surface 26 faces toward the first electrode 1. The inner side surface 16 and the inner side surface 26 face each other. Both of the inner side surface 16 and the inner side surface 26 are flat. The inner side surface 16 is covered by the coating film 61. The inner side surface 26 is covered by the coating film 62. The vertical direction of the first intermediate layer 4 and the second intermediate layer 5 is reversed to that in the chip resistor 101.
The method for manufacturing the chip resistor 104 is the same as the method for manufacturing the chip resistor 101 except that the thickness of the conductive elongated boards 711 (see
According to this variation again, the same advantages as those of the chip resistor 101 are obtained.
In the chip resistor 104, the side surface 14 is not covered by the coating film 61. However, similarly to the first variation of the first embodiment, the side surface 14 of the chip resistor 104 may be covered by the coating film 61. Similarly, in the chip resistor 104, the side surface 24 may be covered by the coating film 62.
The chip resistor 106 includes a first electrode 1, a second electrode 2, a resistor portion 3, a first intermediate layer 4, a second intermediate layer 5, a coating film 61, a coating film 62, oxides 691 (not shown in this embodiment, see
In the chip resistor 106, the first electrode 1 and the second electrode 2 are provided on a same side of the resistor portion 3. As shown in
According to this variation, the same advantages as those of the chip resistor 101 are obtained.
When current flows through the chip resistor 106, the portion of the resistor portion 3 which overlaps the gap between the first electrode 1 and the second electrode 2 as viewed in plan (viewed in the direction Z) functions as a resistor. Thus, the resistance of the chip resistor 106 is determined by the distance between the first electrode 1 and the second electrode 2. By adjusting the distance between the first electrode 1 and the second electrode 2 in the state of the resistor aggregate 703, the resistance of the chip resistor 106 is finely adjusted. By finely adjusting the resistance of the chip resistor 106, the number of chip resistors 106 which require trimming reduces. This enhances the manufacturing efficiency of the chip resistor 106.
In the chip resistor 106, the side surface 14 is not covered by the coating film 61. However, similarly to the first variation of the first embodiment, the side surface 14 of the chip resistor 106 may be covered by the coating film 61. Similarly, the side surface 24 of the chip resistor 106 may be covered by the coating film 62.
The present invention is not limited to the foregoing embodiments. The specific structure of each part of the present invention may be varied in design in many ways.
Although an example in which the side surface 13 is not covered by the coating film 61 is shown, the side surface 13 may be covered by the coating film 61. Similarly, although an example in which the side surface 23 is not covered by the coating film 62 is shown, the side surface 23 may be covered by the coating film 62.
The chip resistor may be made without using a lead frame. For instance, the chip resistor may be made by bonding two separate bars made of an electrically conductive material and a bar made of a resistive material. Although a plurality of chip resistors are collectively punched in the foregoing embodiments, the chip resistors may be punched one by one. Though punching is preferable in terms of the merits described above, other techniques such laser cutting may be employed as the cutting method.
The chip resistor may be manufactured by using reels explained in terms of prior arts.
Number | Date | Country | Kind |
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2011-226646 | Oct 2011 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2012/076481 | 10/12/2012 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/054898 | 4/18/2013 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5287083 | Person | Feb 1994 | A |
5604477 | Rainer | Feb 1997 | A |
6401329 | Smejkal | Jun 2002 | B1 |
7042328 | Schneekloth | May 2006 | B2 |
7053749 | Ishida | May 2006 | B2 |
RE39660 | Szwarc | May 2007 | E |
7217374 | Watanabe | May 2007 | B2 |
8183976 | Lo | May 2012 | B2 |
8319598 | Zandman | Nov 2012 | B2 |
8531264 | Li | Sep 2013 | B2 |
20030201871 | Chern | Oct 2003 | A1 |
20040216303 | Berlin | Nov 2004 | A1 |
20050258930 | Ishida | Nov 2005 | A1 |
20110063072 | Lo | Mar 2011 | A1 |
Number | Date | Country |
---|---|---|
3321724 | Jun 2002 | JP |
2006-60126 | Mar 2006 | JP |
2008-16870 | Jan 2008 | JP |
2009-71123 | Apr 2009 | JP |
2011-159682 | Aug 2011 | JP |
Entry |
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Office Action issued in corresponding Japanese Patent Application No. 2011-226646 on Jan. 26, 2016 (4 pages). |
Number | Date | Country | |
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20140247108 A1 | Sep 2014 | US |