The present invention relates to voltage resistors, and in particular, a high withstand voltage resistor and a manufacturing method for the same.
Conventionally, high voltage resistors have been used in the vicinity of power supplies for household appliances etc. High voltage resistors typically have been designed to have a resistance of 1 MΩ or greater and to withstand a voltage of 1 kV or greater. With such a high voltage resistor, while it is necessary to improve resistance accuracy and withstand voltage, efficiently raising the resistance accuracy is difficult due to the high resistance.
Technologies for increasing resistance accuracy of a resistor are disclosed in, for example, JP 2004-200424A, which discloses techniques for increasing resistance accuracy of a chip resistor. More specifically, multiple thick-film resistive elements having different sheet resistances are formed between a pair of electrodes, and laser trimming is performed to the respective thick-film resistive elements so as to provide a desired resistance. This resistance adjustment method serially connects the multiple resistive elements having different resistances and performs trimming to the resistive element, in order beginning with the element with the largest resistance (thick-film resistive element having the largest sheet resistance) so as to adjust the resistances. As a result, this technique not only makes the manufacturing process complicated due to formation of multiple thick-film resistive elements having different sheet resistances, but also, the resistance adjusting process is also complicated, contributing to the rising cost of manufacturing the resistor itself.
The present invention provides a high voltage resistor capable of improving resistance accuracy while maintaining a high withstand voltage property. A manufacturing method for the same is also provided.
The following configuration, for example, is provided as a means for reaching said aim and resolving the above problems. That is, the present invention is a resistor characterized by including a resistive element electrically conducting between a pair of electrodes formed on an insulating substrate. The resistive element has a first resistive part having a meandering pattern and a swelling pattern that is connected to the meandering pattern and has a form in which a part of the meandering pattern swells out from the stroke width of the meandering pattern, and a second resistive part that is shorter than the entire length of the first resistive part, has a wider width than the stroke width of the meandering pattern, and is electrically connected in series to the first resistive part. A trimming groove is formed in at least either the swelling pattern or the second resistive part.
For example, it is characterized by the second resistive part having a linear form. For example, it is characterized in that width of a remaining part of the second resistive part in a region where the trimming groove of the second resistive part is formed is equal to or greater than width of the meandering pattern.
Alternatively, for example, it is characterized by further including an intermediate electrode connecting the first resistive part and the second resistive part. Further alternatively, for example, it is characterized in that the first resistive part and the second resistive part are constituted by the same resistive material.
The following configuration, for example, is provided as another means for resolving the above problems. That is, the present invention is characterized by a manufacturing method for a resistor having a resistive element electrically conducting between a pair of electrodes formed on an insulating substrate. The manufacturing method includes a forming step of forming a first resistive part having a meandering pattern and a swelling pattern that is connected to the meandering pattern and has a form in which a part of the meandering pattern swells out from the stroke width of the meandering pattern, and a second resistive part that is shorter than the entire length of the first resistive part, has a wider width than the stroke width of the meandering pattern, and is electrically connected in series to the first resistive part; a first trimming step of removing a part of the swelling pattern for adjusting resistance so as to elongate a passage of an electric current of the first resistive part; and a second trimming step of narrowing a width of a predetermined region of the second resistive part for adjusting resistance. The width of the remaining part of the predetermined region of the second resistive part where a trimming groove is formed in the second trimming step is equal to or greater than the width of the meandering pattern.
For example, it is characterized in that trimming in the first trimming step is performed through sand blasting, and trimming in the second trimming step is performed using a laser.
According to the present invention, resistance accuracy of a high voltage resistor may be improved and its high withstand voltage property may be maintained.
Here, the first electrode 11 is arranged at the lower left corner of the insulating substrate 10, the second electrode 15 is arranged at the lower right corner, and the intermediate electrode 13 is arranged on the lower part, slightly to the right from the center. At this time, the position of the lower end of the intermediate electrode 13 is slightly back from, and further on the inner side of the substrate 10 than positions of the first electrode 11 and the second electrode 15. This facilitates forming a protective film described later for covering the intermediate electrode 13, and prevents exposing the intermediate electrode 13 out from the protective film.
Next, at operation S3, resistive elements are formed between the aforementioned electrodes. Here, as shown in
The meandering pattern 23 comprises a resistive element having a meandering form on the substrate. One of its ends is connected to the first electrode 11 and the other end is connected to an end of the swelling pattern 24. The number of turns in this meandering pattern 23 may be arbitrarily set. The swelling pattern 24 is constituted by a resistive element having a form swelling out from the stroke width of the meandering pattern. The coarse adjustment pattern 25 has a form swelling out from the stroke width of the meandering pattern like the swelling pattern 24, and also has the form of a pattern turning around made by removal of the resistive element at the central portion into a rectangular or substantially rectangular shape. The swelling pattern 24 and the coarse adjustment pattern 25 are mutually connected on their respective base sides. Moreover, the meandering pattern 26 comprises a resistive element having a meandering form on the substrate and has one end connected to an end of the coarse adjustment pattern 25 and the other end connected to the intermediate electrode 13.
In the high voltage resistor according to an embodiment of the invention, the first resistive part 21 and the second resistive part 29 are formed by screen printing and baking on the substrate, e.g., a ruthenium oxide (RuO2) paste, as a resistive material. That is, the same resistive material is used for the first resistive part 21 and the second resistive part 29. In some embodiments, different resistive materials may be used instead of the same resistive material for the first resistive part 21 and the second resistive part 29. For example, a material having a lower resistance than the material used for the first resistive part 21 may be used as the resistive material for the second resistive part 29.
In other embodiments, the above resistive elements may have a relationship of L1>L2 where L1 denotes direct distance between the first electrode 11 and the intermediate electrode 13 of the first resistive part 21, and L2 denotes longitudinal direct distance of the second resistive part 29. Here, L1 may be defined as length of the first resistive part 21 and L2 defined as length of the resistive part 29, where the relationship L1>L2 generally holds true in this case as well. Furthermore, in the case where W1 denotes pattern width of the first resistive part 21 and W2 denotes latitudinal width of the second resistive part 29, the resistive elements may be formed so as to satisfy a relationship of W1<W2 (e.g., a relationship such that W2 is twice that of W1.)
Next, a glass film is formed in operation S5 of
At operation S7, resistance is measured. More specifically, probes of a resistance measuring device (e.g., tester) are placed on the first electrode 11 and the intermediate electrode 13 to measure resistance of the first resistive part 21, the probes are then placed on the intermediate electrode 13 and the second electrode 15 so as to measure resistance of the second resistive part 29, and the respective resistance values are then examined to see whether they are within a permissible range.
With the high voltage resistor according to the embodiment, as shown in
In the next step, trimming of the resistive elements is carried out to adjust the resistance values. That is, in operation S9, a trimming groove (also called a V-cut) 35 is formed in the swelling pattern 24 that constitutes the first resistive part 21 as shown in
In the first trimming, removal of a part of the resistive elements from the base side of the swelling pattern 24 toward the front end side thereof so as to form the trimming groove 35 allows elongation of the passage of an electric current between the first electrode 11 and the intermediate electrode 13. In this case, an increase in the length of the trimming groove 35 (trim even deeper along the length of the swelling pattern 24) lengthens an alternative route for current running through the swelling pattern 24, thereby allowing adjustment so as to increase the resistance of the first resistive part 21.
In the case of setting the accuracy of a trimming device used in the above trimming process to ±1%, the first trimming trims R1 to fit a nominal resistance (R1+R2)×0.99±1% while measuring R1+R2. Therefore, it results in (R1+R2)×0.98˜1.00. Note that severing a part (part A in
Next, in operation S11, the remaining part after adjustment in the above first trimming operation is adjusted through a second trimming operation. Here, as shown in
Supposing that W3 denotes the width of the remaining part in a latitudinal direction (vertical direction in
In operation S13, as shown in
Note that with the high voltage resistor according to the above embodiment, the three electrodes of the first electrode 11, the intermediate electrode 13 and the second electrode 15 are formed on the insulating substrate 10, yet are not limited thereto. As a modification of the above-given embodiment, for example, a configuration having the two electrodes of the first electrode 11 and the second electrode 15 formed on the insulating substrate 10 without an intermediate electrode may be provided. More specifically, as shown in
In the case of the high voltage resistor according to the modification illustrated in
As described above, the resistor according to this embodiment includes a resistive element constituted by a first resistive part and a second resistive part, where the first resistive part has a meandering pattern that meanders on the surface of an insulating substrate, and a swelling pattern that has a part of the meandering pattern swelling out from the stroke width, and the second resistive part is shorter than the entire length of the first resistive part and has a wider width than the stroke width of the meandering pattern. Moreover, its configuration in which a trimming groove is formed in at least either the swelling pattern or the second resistive part and then the resistance is adjusted allows for improvement in resistance accuracy while maintaining the high withstand voltage property of the high voltage resistor.
Particularly, in the configuration of the L-shaped trimming groove of the second resistive part, as the width of the remaining part of the region in latitudinal direction where the trimming groove is formed is equal to or greater than the pattern width of the first resistive element, fusion of the resistive elements can be reliably prevented even when a high voltage is applied to the second resistive part.
Number | Date | Country | Kind |
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2014-217820 | Oct 2014 | JP | national |