The present invention relates to multilayer varistors, and more particularly to a multilayer varistor having increased current-carrying area and process for producing the same.
ZnO-based varistors have excellent non-ohm properties and are frequently used in electric systems and circuitries as overvoltage protection devices for protecting electronic elements from damages caused by transient voltage surges.
As electronic products are designed more toward microminiaturization, thinness, integration and versatility, the latest development of ZnO-based varistor is multilayer varistor (hereinafter referred to as MLV).
As shown in
The known MLV 10 as described previously is made using known multilayer technology through the following steps:
The prior known MLV 10 has its disadvantages. Since the lower cap 21, the inner-electrode stack 22 and the upper cap 23 of the ceramic body 20 are made of the same material, the three have equal impedance, and particularly the MLV 10 is prevented from normal function unless the thickness (T) of the lower cap 21 (and the upper cap 23) as well as the margin (H) of the inner electrode 30 are greater than the inner-electrode gap (G). In other words, the following conditions R5-R7 must be satisfied:
More specially, as shown in
Consequently, if the size of the MLV remains unchanged, increase of the number of layers of the inner electrodes 30 is limited as the MLV 10 has to satisfy the foregoing conditions R5-R7. This prevents increase of the current-carrying area of every inner-electrode layer 30, and in turn prevents increase of the overall current-carrying area of the MLV 10.
In view of this, it is an object of the present invention to provide a process for producing a multilayer varistor (MLV) having an increased current-carrying area, and more specially, the inventive MLV is not needed to make dimensionally larger, but it has an increased current-carrying area under requirement of keeping its dimensions the same.
It is another object of the present invention to provide a process for producing a multilayer varistor (MLV) involves to make a lower cap, a upper cap and a margin of inner electrodes formed from a high-impedance material, or alternatively involves to make a MLV sintered body immersed into a low-valence alkali metal ion solution of 5-80% concentration for at least 2 minutes to significantly increase the impedance at the areas at issue, so that to make the thickness of the lower cap and of the upper cap become thinned as well as to make the margin of the inner electrodes become narrowed is possible. In this manner, the MLV with the same dimension as before can have more layers of inner electrodes and in turn increased current-carrying area of every inner-electrode layer as well as increased MLV's overall current-carrying area without dimensionally increasing the MLV, thereby improving the performance of the multilayer varistor.
It is another object of the present invention to provide a multilayer varistor (MLV) comprises a ceramic body having interdigitated inner electrodes inside, and two outer electrodes each covered onto one end of the ceramic body to connect with the interdigitated inner electrodes in electrical connection, wherein the ceramic body is formed from laminating a lower cap, an inner-electrode stack and an upper cap into a unity, and satisfies the following conditions:
It is another object of the present invention to provide a multilayer varistor (MLV) which is produced from the aforesaid process under the control of keeping dimensionally unchanged and has the following beneficial effects:
As shown in
In particular, the ceramic body 20 of the MLV 15 of the present invention is a sandwiched structure formed from laminating a lower cap 24, an inner-electrode stack 25 and an upper cap 26 into a unity, and satisfies the following conditions R1-R4:
Preferably, the ceramic body 20 has the lower cap 24, the inner-electrode stack 25 and the upper cap 26 to satisfy the following conditions K1-K4:
The disclosed multilayer varistor 15 of the present invention may be made using two methods. The first method for making the multilayer varistor 15 involves making the lower cap 24, the upper cap 26, and the margin (h) of the inner electrodes 30 of the multilayer varistor 15 with a material whose impedance is higher than the impedance of the inner-electrode stack 25, so that the disclosed multilayer varistor 15 of the present invention satisfies the foregoing conditions R1-R4 or K1-K4.
The second method for making the multilayer varistor 15 of the invention involves:
Therein, the low-valence alkali metal ions are selected from the group consisting of lithium ions, sodium ions, potassium ions, rubidium ions, cesium ions, and francium ions. Preferably, the alkali metal ions are lithium ions, sodium ions or potassium ions.
Pure ZnO particles were originally insulators. In order to allow pure ZnO particles to display semi-conductive and voltage-dependent properties during proceeding a sintering process, these ZnO particles have to be first doped with high-valence ions and then wrapped by a thin layer of a high-impedance material.
Thus, during preparation of the ceramic body 20 of the disclosed multilayer varistor 15 of the present invention, the step of high-temperature diffusion of low-valence ions as mentioned above was performed on the MLV sintered body, where low-valence alkali metal ions (e.g., one-valence lithium ions) were permeated into the surfaces of all layers of the MLV sintered body, so as to make the ZnO particles less semi-conductive due to the doping of the low-valence alkali metal ions, and have increased impedance.
Hence, the second method of the present invention for preparing the disclosed multilayer varistor 15 is so different from the known MLV making method that such a step of high-temperature diffusion of low-valence ions is additionally performed on the MLV sintered body by immersing the MLV sintered body immersion into a low-valence alkali metal ion solution of 5-80% concentration, preferably 40-80% concentration, for at least 2 minutes, preferably 2-60 minutes, more preferably 5-20 minutes, and most preferably 10-12 minutes.
Therein, the concentration of the alkali metal ion solution and the immersion time determine how deep the low-valence ions go into the layers of the MLV sintered body. After completion of immersion in a solution of low-valence alkali metal ions, the MLV sintered body after dried to removal of water is heated at 650-900° C., preferably 700-900° C., and more preferably 800-875° C. to finish the step of high-temperature diffusion. This step makes the impedance of the lower cap 24, the upper cap 26 and the margin (h) of the inner electrodes 30 in the MLV sintered body higher than the impedance of the inner-electrode gap (g).
The second method of the present invention relates to make the impedance at the surfaces of the layers of the MLV sintered body higher than the impedance at its inner-electrode gap (g). This outstanding phenomenon not only breaks the limitation of the conventional MLV manufacturing method, but also makes the multilayer varistor 15 disclosed by the present invention meaningfully satisfy the foregoing conditions R1-R4 or K1-K4.
More specially, the second method for making the disclosed multilayer varistor 15 of the present invention, as shown in
Under the control of keeping dimensionally unchanged, the multilayer varistor 15 made from the disclosed method of the present invention is favorable to have the following unexpected effects superior to those multilayer varistors commonly known in prior arts:
As far as the multilayer varistor 15 made from the disclosed method of the present invention is concerned, the more layers of inner electrodes 30 have, the more layers of the inner-electrode gap (g) are existed.
More specially, under the control of keeping dimensionally unchanged, the disclosed multilayer varistor 15 of the present invention can advantageously promote to have more layers of inner electrodes 30 and also to increase its own overall current-carrying area thereof, since the multilayer varistor 15 have itself owned how much overall current-carrying area is the product via a mathematical calculation to have a current-carrying area owned by a single inner electrode 30 taken as a multiplicand and get multiplied of the total number of layers of the inner-electrode gap (g) (i.e., which is taken as a multiplier).
Accordingly, the physical performance of the multilayer varistor 15 of the present invention is outstandingly improved without dimensionally making the multilayer varistor 15 larger.
In the following paragraphs, examples will be described for further illustrating the present invention without limiting the scope of the present invention. Those tested samples of multilayer varistors for used in the examples and the comparative examples were produced according to the specifications shown in Table 1, and the tested samples were measured using a surge absorber tester modeled MOV-168 and manufactured by TTK (Think Technologies CO., Ltd., Taiwan) for their respective physical properties.
The multilayer varistors modeled 0805, 1206 and 1210 in Table 2 were taken as subjects.
The sample multilayer varistors for Comparative Examples 1-3 were made using the known MLV manufacturing method, while the sample multilayer varistors for Example 1-3 were prepared using the disclosed method which is different from the known MLV manufacturing method.
The 0805- and 1206-MLV sintered bodies of Examples 1 and 2 is respectively immersed in a lithium-ion solution of 40% concentration for 15 minutes, after drying to removal of water, and then performing the step of high-temperature diffusion of low-valence alkali metal ions at 845° C.
The 1210-MLV sintered body of Example 3 is immersed in a lithium-ion solution of 80% concentration for 12 minutes, after drying it, and then performing the step of high-temperature diffusion of low-valence alkali metal ions at 850° C.
The sample multilayer varistors were measured for their respective physical properties, and the results are show in Table 2.
The sample multilayer varistors of Examples 1-3 and of Comparative Example 1-3 were measured for their basic electrical properties at their outer electrodes such as the breakdown voltage, the nonlinear coefficient and the leakage current, and no significant changes were noticed.
However, according to Table 2, the sample multilayer varistors of Examples 1-3 are far greater than the sample multilayer varistors of Comparative Examples 1-3 in terms of current-carrying capacity. This indicates that the ceramic bodies 20 of the sample multilayer varistors of Examples 1-3 had increased peripheral impedance.
In other words, the results shown in Table 2 indicate during the step of high-temperature diffusion of low-valence ions performed on the sample MLV sintered bodies, by adjusting the concentration of the lithium-ion solution used and the immersion time, the diffusion of the low-valence lithium ions were controlled to only reach the zinc oxide particles in the lower cap 24, in the upper cap 26, and in the margin (h) of the inner electrodes 30 in the MLV sintered bodies, without affecting zinc oxide particles in the inner-electrode gap (g) of the inner-electrode stack 25.
As a result, the impedance at the lower cap 24, the upper cap 26, and the margin (h) of the inner electrodes 30 in the MLV sintered body was increased and became higher than the impedance at the inner-electrode gap (g) of the inner-electrode stack 25.
These results also prove that the multilayer varistor made using the disclosed method can have its lower cap 24 and upper cap 26 thinner and have its margin (h) of the inner electrodes 30 reduced without changing its dimensions.
The multilayer varistors modeled 0805, 1206 and 1210 made as those for Examples 1-3 and Comparative Examples 1-3 were taken as samples of Examples 4-6 and Comparative Examples 4-6, respectively.
The samples were measured for the inner-electrode gap (g), the lower cap's thickness, the upper cap's thickness, the number of inner-electrode layers, every inner-electrode layer's current-carrying area, and the overall current-carrying area thereof, the results are shown in Table 3.
The sample multilayer varistors for Comparative Examples 4-6 were made using the known MLV manufacturing method and are as shown in
On the other hand, the sample multilayer varistors for Examples 4-6 were made using the disclosed method and are as shown in
As the results shown in Table 3, the sample multilayer varistors for Examples 4-6 had 6-8 layers of inner electrodes and total current-carrying area of 14.0-54.6 mm2 compared to 4-6 layers of inner electrodes and total current-carrying area of 5.19-27.4 mm2 of sample multilayer varistors for the Comparative Examples 4-6.
By comparison in respect of physical properties, the sample multilayer varistors for Examples 4-6 are far greater than the sample multilayer varistors for Comparative Examples 4-6 with the same dimensions.
The multilayer varistors modeled 0805 and 2220 made for Example 7 and Example 8 were respectively measured for the inner-electrode gap (g), the lower cap's thickness, the upper cap's thickness, the number of inner-electrode layers, every inner-electrode layer's current-carrying area, and the overall current-carrying area thereof, the results are shown in Table 4.
According to the results shown in Table 4, the sample multilayer varistors for Examples 7-8 were made using the disclosed method and are as shown in
and
The multilayer varistors modeled 0806, 1206, 1208, 1210, 1812, 2220 and 3220 were made using the disclosed method and used as the sample multilayer varistors for Example 9-15.
During performing the step of high-temperature diffusion of low-valence ions, the multilayer varistors (MLV) sintered bodies of Example 9-15 were respectively immersed in lithium-ion solutions of 5-70% concentration according to their respective Li-doping conditions as stated in Table 5 for at least 2 minutes, and, after dried to removal of water, undergone the step of high-temperature diffusion of lithium ions at 650-900° C.
The sample multilayer varistors for Example 9-15 were measured for their respective physical properties, and the results are show in Table 5.
According to the results shown in Table 5, the sample multilayer varistors for Examples 9-15 were made using the disclosed method and are as shown in
In addition, according to the results shown in Table 5, with the same dimensions, the sample multilayer varistors for Examples 9-15 had 2-20 layers of inner electrodes and total current-carrying area of 1.85-441.75 mm2.
Results:
By comparing Examples 1-15 and Comparative Examples 1-6, it is found that the disclosed method and the disclosed multilayer varistor of the present invention achieved more layers of inner electrodes, larger current-carrying area of every inner-electrode layer, and larger overall current-carrying area of the multilayer varistor with the same dimensions, and thus contributed to improve performance of the multilayer varistor outstandingly.
Number | Date | Country | Kind |
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105131098 A | Sep 2016 | TW | national |
Number | Name | Date | Kind |
---|---|---|---|
4675644 | Ott | Jun 1987 | A |
5155464 | Cowman | Oct 1992 | A |
6184769 | Nakamura | Feb 2001 | B1 |
6743381 | Cowman | Jun 2004 | B2 |
7724124 | Lien | May 2010 | B2 |
9236170 | Fu | Jan 2016 | B2 |
20140036408 | Kim | Feb 2014 | A1 |
20160024346 | Inoue | Jan 2016 | A1 |