KR20120007001A - Current detection metal plate resistor and method of producing same - Google Patents

Abstract

Provided are a current detection metal plate resistor capable of suppressing damage to a circuit caused by overcurrent in an electronic device, having excellent heat dissipation, and capable of detecting current with high accuracy, and a method of manufacturing the same. The metal plate resistor 10 includes a metal plate resistor 11, a heat resistant protective layer 12 provided at the center of at least one surface of the metal plate resistor, and a heat resistant protective layer provided at the center of one surface of the metal plate resistor. A pair of base electrode layers 14 provided on one surface of the metal plate resistor so as to cover both ends thereof, and a pair of end electrode layers 15 provided on both ends of the metal plate resistor so as to cover the entire surface of the base electrode layer. Equipped.

Description

Metal plate resistor for current detection and its manufacturing method {CURRENT DETECTION METAL PLATE RESISTOR AND METHOD OF PRODUCING SAME}

The present invention provides a current detecting metal sheet resistor having excellent heat dissipation that can detect current with high accuracy even when a large current flows in a specific wiring portion, and can suppress damage to a circuit in an electronic device, and a manufacturing method thereof. It is about.

In order to provide a protection function of the circuit against overcurrent in an electronic device, the use of the current-detection resistor using the metal plate resistor is performed. This current detection resistor is provided in order to detect the current of a specific wiring portion, and it is necessary to detect the current by a resistor having a small resistance value of several mΩ to several tens of mΩ with high accuracy. In addition, this resistor is designed to increase the rated power and to lower the resistance value in order to be able to detect even a large current flowing through the electronic device.

However, such a design has a problem in that heat is generated by a large current, which causes thermal damage to the wiring board.

Thus, in order to avoid such thermal damage, a resistor in which a thick protective layer is formed using a transfer mold technique is known.

As a resistor provided with such a protective layer, for example, as shown in FIG. 3, the metal plate resistor 31, the pair of electrode layers 32 provided in the both ends of this resistor 31, and this electrode layer 32 ) And a resistor 30 including an insulating protective layer 33 provided on the upper and lower surfaces of the resistor 31 is known (see Patent Documents 1 and 2).

However, even in the resistor having such a structure, the avoidance of thermal damage by a large current is not sufficient, and further development of a current detection resistor excellent in heat dissipation is desired.

Japanese Patent Publication No. 2007-220859 (Fig. 7) Japanese Patent Laid-Open No. 6-20802

DISCLOSURE OF THE INVENTION An object of the present invention is to provide a current detection metal sheet resistor capable of suppressing damage to a circuit caused by overcurrent in an electronic device, having excellent heat dissipation, and capable of detecting current with high accuracy, and a method of manufacturing the same. have.

According to the present invention, the metal plate resistor is formed so as to cover both ends of the metal plate resistor, the heat resistant protective layer provided at the center of at least one surface of the metal plate resistor, and the heat resistant protective layer provided at the center of one surface of the metal plate resistor. Provided is a metal sheet resistor for current detection provided with a pair of base electrode layers provided on one surface of and a pair of end face electrode layers provided on both ends of the metal plate resistor so as to cover the entire surface of the base electrode layer.

Moreover, according to this invention, the process (a) of screen-printing and hardening a heat resistant protective layer in the center part of the at least one surface of a strip-shaped metal plate resistor, and the heat resistant protective layer provided in the center part of one surface of this metal plate resistor (B) screen-printing and hardening a pair of base electrode layers on one surface of a metal plate resistor so as to cover both ends of the step; and forming a single-side electrode layer by a plating method so as to cover the entire surface of the base electrode layer. c) and a step (d) of cutting a band-shaped metal sheet resistor at predetermined intervals, thereby providing a method for producing a metal sheet resistor for current detection.

The said heat resistant protective layer can be provided in the center part of one surface of a metal plate resistor, and the whole surface of the other surface of a metal plate resistor, and can also be provided in the center part of both surfaces of a metal plate resistor. In the case where the heat resistant protective layer is provided at the centers of both surfaces of the metal plate resistor, the effective electrode is extended by extending the single-sided electrode layer over the partial surface of the surface of the metal plate resistor not provided with the base electrode layer without the heat resistant protective layer. The area can be widened and the heat dissipation efficiency can be further increased.

As a heat resistant protective layer, well-known heat resistant resin can be used, Especially the use of the polyamide-imide resin which shows the outstanding heat resistance and insulation even if it is a thin film is preferable. Moreover, the printing characteristic at the time of manufacture can be improved by containing a silica powder in this heat resistant resin layer. In particular, by blending powders having different particle diameters of the micrometer order and the nanometer order as silica powder, shading and bleeding, etc. during printing can be effectively prevented, and the accuracy of the width dimension of the heat resistant protective layer is improved. This can suppress nonuniformity in appearance resistance value.

The compounding ratio of silica powder is 30-55 mass% normally with respect to the total amount with a heat resistant resin, Preferably it is 40-50 mass%. Moreover, when mix | blending the powder which has a different particle diameter of a micrometer order and a nanometer order, 18-40 mass% of former and 12-15 mass% of the latter can be normally made with respect to the total amount with a heat resistant resin.

In addition, silica may be blended in addition to minutes, the black pigments, such as _{CuO, Fe 2 O 3, Mn} 2 O 3.

The base electrode layer can be screen printed and can be formed by a known electrode material such as a thermosetting metal-containing conductive resin paste.

In the present invention, since the base electrode layer is formed so as to cover both ends of the heat resistant protective layer and is entirely covered by the single-sided electrode layer, in order to improve the adhesion to the heat resistant protective layer, printing characteristics, etc., the base electrode layer is formed of silver powder. It is preferable to form by the paste containing a phenol epoxy resin. By using silver powder, thermal conductivity can also be improved and it also contributes to the heat radiating effect of the resistor itself.

The single-sided electrode layer can be formed by a plating method, and can be usually formed by a known electrode material including a copper plating layer, a nickel plating layer and a tin plating layer.

The metal plate resistor is not particularly limited as long as it is a metal plate having a desired resistance value. For example, a Cu-Mn metal plate, a Ni-Cr metal plate, or a Fe-Cr metal plate can be used.

The metal sheet resistor for current detection of the present invention is particularly effective because it has a heat resistant protective layer, a base electrode layer covering both ends of the heat resistant protective layer, and a cross-sectional electrode layer covering the entire surface of the base electrode layer. The area can be widened and excellent heat dissipation can be ensured even when the rated power is set high. Therefore, the metal plate resistor of this invention can suppress the damage to the circuit by the overcurrent in an electronic device, can detect an electric current with high precision, and can contribute also to the miniaturization and thickness of an electronic device.

BRIEF DESCRIPTION OF THE DRAWINGS It is sectional drawing of the metal plate resistor for current detection which shows one Embodiment of this invention.
2 is a cross-sectional view of a metal sheet resistor for current detection, showing another embodiment of the present invention.
3 is a cross-sectional view of a metal sheet resistor for current detection having a conventional heat resistant protective layer.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described with reference to drawings.

1 is a cross-sectional view of a metal sheet resistor 10 for current detection showing an embodiment of the present invention. In FIG. 1, 11 is a metal plate resistor which has a resistance function, The 1st heat resistant protective layer 12 and the whole width direction whole surface of the metal plate resistor 11 are located in the substantially center part on the upper and lower surfaces of this metal plate resistor 11. The second heat resistant protective layer 13 is provided.

Both end portions of the first heat resistant protective layer 12 are covered with both end portions thereof, and a part of the first heat resistant protective layer 12 is in contact with the upper surface of the metal plate resistor 11 so as to leave a part of the upper surface on both end sides of the metal plate resistor 11. A pair of conductive base electrode layers 14 are provided.

The pair of base electrode layers 14 are covered by a pair of single-sided electrode layers 15 so as to cover the entire surface, and the pair of single-sided electrode layers 15 cover the cross section of the metal plate resistor 11 as shown. It coats and extends to the both ends of the 2nd heat resistant protective layer 13 provided in the center part of the lower surface of this metal plate resistor 11, respectively.

A third heat resistant protective layer 16 is formed in the upper gap portion of the pair of cross-sectional electrode layers 15 as shown in the figure. This heat resistant protective layer 16 can be formed of the same material as the 1st and 2nd heat resistant protective layers 12 and 13, but it is not an essential structure in this invention.

The metal sheet resistor 10 for current detection shown in FIG. 1 is of a type in which a portion of the lower surface electrode layer 15 is mounted on a substrate by soldering or the like.

2 is a cross-sectional view of a metal sheet resistor 20 for current detection, showing another embodiment of the present invention. In FIG. 2, 21 is a metal plate resistor having a resistance function, and the first heat resistant protective layer 22 is provided on the entire surface in the width direction of the metal plate resistor 21 at an approximately center portion on the bottom surface of the metal plate resistor 21. It is. Moreover, the 2nd heat resistant protective layer 23 is provided in the whole surface on the metal plate resistor 21.

Both end portions of the second heat resistant protective layer 23 are covered with both end portions thereof, and a part of the second heat resistant protective layer 23 is in contact with the bottom surface of the metal plate resistor 21 to cover the entire lower surface of both ends of the metal plate resistor 21. A pair of conductive base electrode layers 24 are provided.

The pair of base electrode layers 24 are covered by a pair of single-sided electrode layers 25 so as to cover the entire surface, and the pair of single-sided electrode layers 25 cover the cross section of the metal plate resistor 21 as shown. It is formed by covering.

The metal sheet resistor 20 for current detection shown in FIG. 2 is of a type in which a portion of the lower surface electrode layer 25 is mounted on a substrate by soldering or the like.

The manufacturing method of this invention includes the process (a) of screen-printing and hardening a heat resistant protective layer in the center part of the at least one surface of a strip | belt-shaped metal plate resistor. In the manufacturing method of this invention, as shown to FIG. 1 and FIG. 2, a heat resistant protective layer can also be screen-printed and hardened also on the other surface of a strip | belt-shaped metal plate resistor.

The strip-shaped metal sheet resistor is finally cut at predetermined intervals to form a desired metal sheet resistor, and is used to form the heat resistant protective layer, the base electrode layer, and the single-side electrode layer required before the cutting, for example, a Cu-Mn system. A strip metal, a Ni-Cr strip metal, and a Fe-Cr strip metal can be used.

Here, as a strip | belt-shaped metal plate resistor, it is preferable at the point which does not reduce the spring property of a metal plate resistor using the thing which has not been annealed after final rolling. When the spring property of a strip | belt-shaped metal plate resistor falls, it cannot be restored when a strip | belt-shaped metal plate resistor is bent in a manufacturing process of a resistor, and it may become a defective article.

A heat resistant protective layer can be formed by screen-printing the heat resistant resin paste which disperse | distributed the polyamideimide resin containing a silica powder to a solvent, for example, and heat-hardening to about 80-300 degreeC.

The manufacturing method of this invention screen-prints and hardens a pair of base electrode layer on one surface of a metal plate resistor so that it may cover both ends of the heat resistant protective layer provided in the center part of one surface of a metal plate resistor. It includes.

The base electrode layer can be formed by, for example, screen printing a thermosetting metal-containing conductive resin paste containing silver powder and a phenol epoxy resin and heating and curing it at about 80 to 300 ° C.

The manufacturing method of this invention includes the process (c) of forming a cross-sectional electrode layer by a plating method so that the base electrode layer whole surface may be covered.

The single-sided electrode layer can be formed, for example, by plating copper (Cu), nickel (Ni), tin (Sn), other metals, or alloys thereof alone or in combination.

The manufacturing method of this invention includes the process (d) which cut | disconnects a strip | belt-shaped metal plate resistor at predetermined intervals.

By the step (d), a desired current detection metal plate resistor can be obtained, and the heat resistant resin layer, the base electrode layer, and the cross-sectional electrode layer are not formed on the respective metal plate resistors, but at the same time as the strip-shaped metal plate resistors, so that the production efficiency is achieved. This is excellent.

(Example)

EMBODIMENT OF THE INVENTION Next, although the Example of this invention is described with reference to drawings, this invention is not limited to these.

(Example 1)

Manufacture of metal plate resistor 10 shown in FIG.

A polyamideimide resin paste containing silica powder is applied by screen printing to a central portion of the upper and lower surfaces of the Cu-Mn-based strip-shaped metal sheet resistor after the final rolling, which is 200 ° C for 10 minutes at 100 ° C. 10 minutes and at 250 degreeC for 30 minutes, it hardened | cured and the 1st heat resistant protective layer 12 and the 2nd heat resistant protective layer 13 were formed.

Here, the used resin paste is a crystalline silica powder having an average particle diameter of 4 μm and 3.5 to 4.5 μm particle diameter, 36 mass% with respect to the total amount of the polyamideimide resin and the silica powder, and a synthetic silica powder having an average particle diameter of 20 nm, using the polyamideimide resin and silica. The polyamide-imide resin paste containing 10 mass% with respect to the total amount of minutes was used. In this resin paste, about 4% by mass of the synthetic silica powder having an average particle diameter of 20 nm is hardened to a silica powder having a particle diameter of 2 to 5 nm by sol-gel reaction or the like, and the silica powder having a different particle diameter is uniform in the resulting heat resistant resin layer. Can be dispersed.

Next, the silver powder, the phenol epoxy resin, and the solvent are applied so as to overlap the left and right ends of the first heat resistant protective layer 12 on the upper surface of the band-shaped metal plate resistor, and a part to contact the upper surface of the band-shaped metal plate resistor. The silver powder containing conductive resin paste kneaded was applied by a screen printing method, heated at 200 ° C. for 30 minutes, and cured to form a pair of base electrode layers 14.

Subsequently, as shown in FIG. 1, copper plating, nickel plating, and tin plating are plated in this order by the electroplating method so as to cover the pair of base electrode layers 14, and the pair of end electrode layers 15 are covered. Formed.

Next, similarly to the formation of the first heat resistant protective layer 12 and the second heat resistant protective layer 13, the third heat resistant protective layer 16 was formed in the gap between the pair of end face electrode layers 15.

Finally, the strip-shaped metal sheet resistor was cut at predetermined intervals to manufacture a metal sheet resistor 10 for current detection.

(Example 2)

Manufacture of metal plate resistor 20 shown in FIG.

Polyamideimide resin paste containing silica powder was applied by screen printing to the central portion and the entire upper surface of the lower surface of the Cu-Mn-based strip-shaped metal sheet resistor not subjected to annealing after the final rolling. It heat-hardened and the 1st heat resistant protective layer 22 and the 2nd heat resistant protective layer 23 were formed.

Next, silver powder and phenol are overlapped on both left and right ends of the second heat resistant protective layer 23 on the lower surface of the band-shaped metal plate resistor, and a part is in contact with the bottom surface of the band-shaped metal plate resistor. The silver powder containing conductive resin paste which knead | mixed an epoxy resin and a solvent was apply | coated and hardened by the screen printing method, and the base electrode layer 24 of a pair was formed.

Subsequently, as shown in Fig. 2, copper plating, nickel plating, and tin plating are plated in this order by the electroplating method so as to cover the pair of base electrode layers 24, and the pair of end electrode layers 25 are covered. Formed.

Finally, the strip-shaped metal sheet resistor was cut at predetermined intervals to manufacture a metal sheet resistor 20 for current detection.

The heat resistant protective layers in the metal sheet resistors obtained in Examples 1 and 2 were all nonuniform in width dimension and had no shape cracking at the edges.

In addition, since the heat resistant protective layer contained silica powder having a different particle diameter, and the base electrode layer contained silver powder, the contact surfaces of the heat resistant protective layer, the base electrode layer, and the single-side electrode layer were firmly in contact with each other.

(Test example)

The following performance test was done using two types of metal plate resistors from which the resistance value manufactured similarly to Example 1, and two types of metal plate resistors from the conventional resistance value shown in FIG. 3 were used. In addition, it manufactured with the material similar to Example 1 except not including a base electrode layer as a material which comprises each member of the conventional metal plate resistor.

Each metal plate resistor is placed on a glass epoxy substrate coated with 70 μm Cu foil, and the substrate is surrounded by a non-winding state, and 19.8 A is applied to each metal plate resistor having a resistance value of 5.1 mΩ and 20.3 for each metal plate resistor having a resistance value of 4.84 mΩ. The current of A was energized for 15 minutes each. The surface temperature of the upper surface center part and the cross-sectional electrode layer of the metal plate resistor before and after energization was measured by installing a thermometer at the position of 1 cm above the center part of the metal plate resistor and the cross-sectional electrode layer. Table 1 shows the results of using each metal plate resistor with a resistance value of 5.1 mΩ and Table 2 shows the result of using each metal plate resistor with a resistance value of 4.84 mΩ.

Measurement point Energized temperature
(℃) Temperature after energization
(℃) Temperature rise after application of electricity (℃) Example 1
Center 27.3 102.3 75.0 Single side electrode layer 27.3 95.7 68.4 Conventional
Center 29.1 117.2 88.1 Single side electrode layer 29.1 101.5 72.4

Measurement point Energized temperature
(℃) Temperature after energization
(℃) Temperature rise after application of electricity (℃) Example 1
Center 26.9 103.7 76.8 Single side electrode layer 26.9 98.2 71.3 Conventional
Center 28.0 116.5 88.5 Single side electrode layer 28.0 97.4 69.4

From the results in Tables 1 and 2, in any case, the base electrode layer of Example 1 of the present invention was provided rather than the conventional metal plate resistor, and the area of the cross-sectional electrode layer was increased to increase the temperature at the center and the surface of the cross-sectional electrode layer. It turned out that this was small and the heat dissipation effect was excellent.

10, 20... Metal sheet resistors 11 and 21 for current detection. Metal plate resistor
12, 22... First heat resistant protective layer 13, 23... Second heat resistant protective layer
14, 24... Base electrode layers 15, 25. Single-sided electrode layer
16... Third heat resistant protective layer

Claims (11)

On one surface of the metal plate resistor to cover both ends of the metal plate resistor, the heat resistant protective layer provided on the center of at least one surface of the metal plate resistor, and the heat resistant protective layer provided on the center of one surface of the metal plate resistor. A pair of base electrode layers provided and a pair of cross-sectional electrode layers provided at both ends of the metal plate resistor so as to cover the entire surface of the base electrode layer. The method of claim 1,
The heat resistant protective layer is provided in the center part of one surface of a metal plate resistor, and the whole surface of the other surface of a metal plate resistor, The metal plate resistor for current detections characterized by the above-mentioned. The method of claim 1,
The heat resistant protective layer is provided at the centers of both sides of the metal plate resistor, and the cross-sectional electrode layer extends over the partial surface which does not have a heat resistant protective layer on the surface of the metal plate resistor without the base electrode layer. Metal plate resistors. The method according to any one of claims 1 to 3,
The heat resistant protective layer is a polyamide-imide resin layer containing silica powder. The method of claim 4, wherein
A metal sheet resistor for current detection, wherein the silica powder is a powder having different particle diameters of the micrometer order and the nanometer order. 6. The method according to any one of claims 1 to 5,
A metal sheet resistor for current detection, wherein the underlying electrode layer comprises silver powder and a phenol epoxy resin. The method according to any one of claims 1 to 6,
A metal sheet resistor for current detection, characterized in that the single-sided electrode layer comprises a copper plating layer, a nickel plating layer and a tin plating layer. (A) screen-printing and hardening a heat resistant protective layer at the center part of at least one surface of a strip | belt-shaped metal plate resistor,
(B) screen-printing and hardening a pair of base electrode layers on one surface of a metal plate resistor so that the both ends of the heat resistant protective layer provided in the center part of one surface of this metal plate resistor may be covered,
(C) forming a single-sided electrode layer by a plating method so as to cover the entire surface of the base electrode layer;
And a step (d) of cutting the band-shaped metal sheet resistor at predetermined intervals. The method of claim 8,
The process (a) WHEREIN: The heat-resistant protective layer is formed by screen-printing and hardening the polyamide-imide resin paste containing a silica powder, The manufacturing method of the metal plate resistor for current detection characterized by the above-mentioned. The method of claim 9,
A silica powder is a powder having a different particle diameter of a micrometer order and a nanometer order. The method according to any one of claims 8 to 10,
The process (b) WHEREIN: The base electrode layer is formed by screen-printing and hardening paste containing silver powder and a phenol epoxy resin, The manufacturing method of the metal sheet resistor for current detection characterized by the above-mentioned.

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