TWM446416U - Over-current protection device - Google Patents
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本創作係關於一種過電流保護元件,特別是關於一種表面黏著型過電流保護元件。This creation relates to an overcurrent protection component, and more particularly to a surface mount overcurrent protection component.
過電流保護元件被用於保護電路,使其免於因過熱或流經過量電流而損壞。過電流保護元件通常包含兩電極及位在兩電極間之電阻材料。此電阻材料具正溫度係數(Positive Temperature Coefficient;PTC)特性,亦即在室溫時具低電阻值,而當溫度上升至一臨界溫度或電路上有過量電流產生時,其電阻值可立刻跳升數千倍以上,藉此抑制過量電流通過,以達到電路保護之目的。當溫度降回室溫後或電路上不再有過電流的狀況時,過電流保護元件可回復至低電阻狀態,而使電路重新正常操作。此種可重複使用的優點,使PTC過電流保護元件取代保險絲,而被更廣泛運用在高密度電子電路上。An overcurrent protection component is used to protect the circuit from damage due to overheating or flow through current. The overcurrent protection component typically comprises two electrodes and a resistive material positioned between the two electrodes. The resistive material has a positive temperature coefficient (PTC) characteristic, that is, has a low resistance value at room temperature, and when the temperature rises to a critical temperature or an excessive current is generated on the circuit, the resistance value can jump immediately. It is thousands of times higher, so as to suppress the passage of excessive current to achieve the purpose of circuit protection. When the temperature drops back to room temperature or there is no more overcurrent on the circuit, the overcurrent protection component can return to a low resistance state, causing the circuit to resume normal operation. This reusable advantage makes PTC overcurrent protection components replace fuses and is more widely used in high density electronic circuits.
參照圖1,美國專利號US 6,377,467揭示一種表面黏著型過電流保護元件10,其包含電阻元件11、第一電極17、第二電極18、絕緣層15和16、第一導電通孔19及第二導電通孔20。電阻元件11包含第一導電構件13、第二導電構件14及高分子材料層12。高分子材料層12係疊設於第一導電構件13 及第二導電構件14之間。第一電極17包含一對分別設置於絕緣層15和16表面之電極箔,且與第一導電通孔19連接。第二電極18包含一對分別設置於絕緣層15和16表面之電極箔,且與第二導電通孔20連接。導電通孔19、20係位於二個側表面的約中央部位且為半圓孔之設計。Referring to Fig. 1, U.S. Patent No. 6,377,467 discloses a surface-adhesive overcurrent protection element 10 comprising a resistive element 11, a first electrode 17, a second electrode 18, insulating layers 15 and 16, a first conductive via 19 and a Two conductive vias 20. The resistive element 11 includes a first conductive member 13 , a second conductive member 14 , and a polymer material layer 12 . The polymer material layer 12 is stacked on the first conductive member 13 And between the second conductive members 14. The first electrode 17 includes a pair of electrode foils respectively disposed on the surfaces of the insulating layers 15 and 16, and is connected to the first conductive via 19. The second electrode 18 includes a pair of electrode foils respectively disposed on the surfaces of the insulating layers 15 and 16, and is connected to the second conductive via 20. The conductive vias 19, 20 are located at approximately the center of the two side surfaces and are designed as semi-circular holes.
未來的電子產品,將朝著具有輕、薄、短、小的趨勢發展,以使得電子產品能更趨於迷你化。因此過電流保護元件亦不斷朝小型化的規格演進,從1210、1206、0805、0603、0402甚至已有0201規格的需求。而當規格縮小至0603規格以下時,以半圓孔設計之導電通孔19、20卻可能造成生產製作上的問題。Future electronic products will develop toward a light, thin, short, and small trend, so that electronic products can be more miniaturized. Therefore, the overcurrent protection component has also evolved toward miniaturized specifications, and there are even requirements for the 0201 specification from 1210, 1206, 0805, 0603, 0402. When the specification is reduced to below the 0603 specification, the conductive vias 19 and 20 designed with semicircular holes may cause problems in production.
參照圖2A及圖2B,當元件尺寸愈來愈小時,導電通孔19和20的孔徑一般將依比例隨之減小。例如當元件為0603規格時,半圓孔的半徑僅約為0.15mm。當製作過程中進行元件切割(切粒)時,刀具寬度d必須準確對應於切割道的位置(參圖2A),然而若刀具寬度d位置有偏移時,因孔徑減小,很可能將一側之導電通孔的半圓孔切除大部分,甚至半圓孔被整個切除(參圖2B)。為避免此問題,小型化之元件常會搭配較大的半圓孔設計。然而,較大的半圓孔設計又將產生如下所述在製作流 程上問題。Referring to Figures 2A and 2B, as the component size becomes smaller, the apertures of the conductive vias 19 and 20 will generally decrease in proportion. For example, when the component is 0603, the radius of the semicircular hole is only about 0.15 mm. When the component is cut (grained) during the manufacturing process, the tool width d must correspond exactly to the position of the cutting track (see Fig. 2A). However, if the tool width d is offset, the aperture is likely to be reduced. The semi-circular holes of the conductive vias on the side are mostly cut off, and even the semi-circular holes are completely cut off (see Fig. 2B). To avoid this problem, miniaturized components often match larger semi-circular holes. However, the larger semi-circular hole design will again produce the flow as described below On the issue.
當過電流保護元件10在進行外觀檢測、電阻量測及包裝時會在送料軌道24內推送前進。當元件10的半圓孔較小時,可順利推送前進,如圖3A所示。若當元件10具有大型的半圓孔時,因半圓孔變大的關係,尤其是當半圓孔的凹陷寬度達到所在側邊寬度的一半以上時,在推送時相鄰的元件10容易會有凸出部分卡入半圓孔內,而造成推送不順、卡料等等問題發生,如圖3B所示。When the overcurrent protection element 10 is subjected to appearance detection, resistance measurement, and packaging, it is pushed forward in the feed rail 24. When the semicircular hole of the element 10 is small, the advancement can be smoothly performed as shown in Fig. 3A. If the element 10 has a large semi-circular hole, the adjacent element 10 tends to bulge during pushing, because the semi-circular hole becomes larger, especially when the concave width of the semi-circular hole reaches half or more of the width of the side. Some of the cards are stuck in the semi-circular holes, causing problems such as poor pushing, jamming, and the like, as shown in FIG. 3B.
因此在元件形狀因數(form factor)規格已要求至0603甚至0402時,如何克服上述製作上的問題,業界極需相關的解決方案。Therefore, when the component form factor specification has been required to 0603 or even 0402, how to overcome the above manufacturing problems, the industry needs a related solution.
本創作係關於一種過電流保護元件,特別是關於一種表面黏著型過電流保護元件,其可符合元件小型化趨勢之需求,例如0603、0402或更小規格的要求。This creation relates to an overcurrent protection component, and more particularly to a surface-adhesive overcurrent protection component that meets the requirements of component miniaturization, such as 0603, 0402 or smaller.
根據本創作一實施例之過電流保護元件,其具有相對之上表面、下表面及四個側表面,該四個側表面連接上表面和下表面,且相鄰之側表面構成四個轉角。過電流保護元件包括:PTC材料層、第一導電層、第二導電層、第一電極層、第二電極層及四 個導電通孔。PTC材料層具有第一表面、第二表面,第二表面係位於該第一表面相對側。第一導電層物理接觸該PTC材料層之第一表面,而第二導電層物理接觸該PTC材料層之第二表面。第一電極層包含一對形成於上表面及下表面之第一金屬箔。第一電極層電氣連接第一導電層,且和第二導電層電氣隔離。第二電極層包含一對形成於上表面及下表面之第二金屬箔。第二電極層電氣連接第二導電層,且和第一導電層電氣隔離。四個導電通孔形成於該四個轉角處,其中兩個導電通孔連接該對第一金屬箔及第一導電層,另兩個導電通孔連接該對第二金屬箔及第二導電層。四個導電通孔的截面積總和佔該過電流保護元件之形狀因數面積之比例介於7~20%。An overcurrent protection element according to an embodiment of the present invention has an opposite upper surface, a lower surface, and four side surfaces, the four side surfaces joining the upper surface and the lower surface, and the adjacent side surfaces constituting four corners. The overcurrent protection component includes: a PTC material layer, a first conductive layer, a second conductive layer, a first electrode layer, a second electrode layer, and four Conductive through holes. The PTC material layer has a first surface, a second surface, and the second surface is located on an opposite side of the first surface. The first conductive layer physically contacts the first surface of the PTC material layer, and the second conductive layer physically contacts the second surface of the PTC material layer. The first electrode layer includes a pair of first metal foils formed on the upper surface and the lower surface. The first electrode layer is electrically connected to the first conductive layer and electrically isolated from the second conductive layer. The second electrode layer includes a pair of second metal foils formed on the upper surface and the lower surface. The second electrode layer is electrically connected to the second conductive layer and is electrically isolated from the first conductive layer. Four conductive vias are formed at the four corners, wherein two conductive vias connect the pair of first metal foils and the first conductive layer, and the other two conductive vias connect the pair of second metal foils and the second conductive layer . The sum of the cross-sectional areas of the four conductive vias occupies 7-20% of the shape factor area of the overcurrent protection component.
一實施例中,本創作之過電流保護元件係應用於0603規格,各該導電通孔的面積在0.025~0.042mm2 的範圍。In one embodiment, the overcurrent protection component of the present invention is applied to the 0603 specification, and the area of each of the conductive vias is in the range of 0.025 to 0.042 mm 2 .
另一實施例中,本創作之過電流保護元件係應用於0402規格,各該導電通孔的面積在0.009~0.020mm2 的範圍。In another embodiment, the overcurrent protection component of the present invention is applied to the 0402 specification, and the area of each of the conductive vias is in the range of 0.009 to 0.020 mm 2 .
根據本創作之設計,當元件作的更小時,其導電通孔可被允許製作的較大,進而提供元件進行切粒時較大之容差(tolerance)。另外,在外觀檢測、電阻 量測及包裝時也不會因為導電通孔較大而產生卡料等情況。因此,本創作不僅可提升生產速度,且對於生產良率亦有一定助益。According to the design of the present invention, when the component is made smaller, the conductive via hole can be allowed to be made larger, thereby providing a larger tolerance for the component to perform pelletizing. In addition, in appearance detection, resistance When measuring and packaging, there will be no jamming due to the large conductive through holes. Therefore, this creation not only improves production speed, but also contributes to production yield.
為讓本創作之上述和其他技術內容、特徵和優點能更明顯易懂,下文特舉出相關實施例,並配合所附圖式,作詳細說明如下:In order to make the above-mentioned and other technical contents, features and advantages of the present invention more comprehensible, the related embodiments are described below, and the detailed description is as follows:
圖4A係本創作一實施例之過電流保護元件之立體結構示意圖。過電流保護元件40約為長方體結構,具有相對之上表面、下表面及四個側表面。四個側表面連接上表面和下表面,且相鄰之側表面構成四個轉角。過電流保護元件40包括:一PTC材料層41、第一導電層42、第二導電層43、第一絕緣層44、第二絕緣層45、第一電極層46、第二電極層47及四個導電通孔48。PTC材料層41具有第一表面411和第二表面412,第二表面412係位於該第一表面411相對側。第一導電層42物理接觸該PTC材料層41之第一表面411,第二導電層43則物理接觸該PTC材料層41之第二表面412。第一電極層46包含一對形成於上表面及下表面之第一金屬箔461。第一電極層46電氣連接第一導電層42,且和第二導電層43電氣隔離。第二電極層47包含一對形成於上表面及下表面之第二金屬箔 471。第二電極層47電氣連接第二導電層43,且和第一導電層42電氣隔離。相鄰之側表面構成的四個轉角處設有四個導電通孔48,其中兩個導電通孔48連接該對第一金屬箔461及第一導電層42,另兩個導電通孔48連接該對第二金屬箔471及第二導電層43。4A is a schematic perspective view showing the overcurrent protection component of an embodiment of the present invention. The overcurrent protection element 40 is approximately a rectangular parallelepiped structure having an opposite upper surface, a lower surface, and four side surfaces. The four side surfaces connect the upper surface and the lower surface, and the adjacent side surfaces constitute four corners. The overcurrent protection component 40 includes a PTC material layer 41, a first conductive layer 42, a second conductive layer 43, a first insulating layer 44, a second insulating layer 45, a first electrode layer 46, a second electrode layer 47, and four. Conductive vias 48. The PTC material layer 41 has a first surface 411 and a second surface 412, the second surface 412 being located on the opposite side of the first surface 411. The first conductive layer 42 physically contacts the first surface 411 of the PTC material layer 41, and the second conductive layer 43 physically contacts the second surface 412 of the PTC material layer 41. The first electrode layer 46 includes a pair of first metal foils 461 formed on the upper surface and the lower surface. The first electrode layer 46 is electrically connected to the first conductive layer 42 and is electrically isolated from the second conductive layer 43. The second electrode layer 47 includes a pair of second metal foils formed on the upper surface and the lower surface 471. The second electrode layer 47 is electrically connected to the second conductive layer 43 and is electrically isolated from the first conductive layer 42. Four conductive through holes 48 are formed at four corners formed by adjacent side surfaces, wherein two conductive through holes 48 connect the pair of first metal foil 461 and the first conductive layer 42, and the other two conductive through holes 48 are connected. The pair of second metal foil 471 and second conductive layer 43.
第一絕緣層44形成於第一導電層42表面,而第二絕緣層45形成於該第二導電層43表面。其中形成於上表面之第一金屬箔461及第二金屬箔471係形成於第一絕緣層44表面,而形成於下表面之第一金屬箔461及第二金屬箔471係形成於第二絕緣層45表面。The first insulating layer 44 is formed on the surface of the first conductive layer 42, and the second insulating layer 45 is formed on the surface of the second conductive layer 43. The first metal foil 461 and the second metal foil 471 formed on the upper surface are formed on the surface of the first insulating layer 44, and the first metal foil 461 and the second metal foil 471 formed on the lower surface are formed in the second insulation. Layer 45 surface.
一實施例中,第一防焊層53形成於位於上表面之第一金屬箔461和第二金屬箔471之間的該第一絕緣層44表面。第二防焊層54形成於位於下表面之第一金屬箔461和第二金屬箔471之間的該第二絕緣層45表面。In one embodiment, the first solder resist layer 53 is formed on the surface of the first insulating layer 44 between the first metal foil 461 and the second metal foil 471 on the upper surface. The second solder resist layer 54 is formed on the surface of the second insulating layer 45 between the first metal foil 461 and the second metal foil 471 on the lower surface.
本實施例之導電通孔48的截面形狀係約成1/4圓孔。此外,導電通孔的截面形狀亦可為弧形、方形、長方形、三角形或多邊形,而為本創作所涵蓋。The cross-sectional shape of the conductive via 48 of this embodiment is about 1/4 round. In addition, the cross-sectional shape of the conductive via may also be curved, square, rectangular, triangular or polygonal, and is covered by the creation.
圖4B為第一導電層42與PTC材料層41之上視圖,圖4C則為第二導電層43和PTC材料層41之底視圖。同時參考圖4A及4B,第二側表面62位 於第一側表面61之相對側。第一導電層42延伸至第一側表面61,且與第二側表面62間有第一缺口51。同時參考圖4A及4C,第二導電層43延伸至該第二側表面62,且與該第一側表面61有第二缺口52。4B is a top view of the first conductive layer 42 and the PTC material layer 41, and FIG. 4C is a bottom view of the second conductive layer 43 and the PTC material layer 41. 4A and 4B, the second side surface 62 On the opposite side of the first side surface 61. The first conductive layer 42 extends to the first side surface 61 and has a first gap 51 between the second side surface 62 and the second side surface 62. 4A and 4C, the second conductive layer 43 extends to the second side surface 62 and has a second gap 52 with the first side surface 61.
申言之,PTC材料層41的上下表面,分別設置有第一導電層42與第二導電層43,且各自延伸至相對兩側表面61及62。此導電層42、43可由平面金屬簿膜,經如雷射切除,化學蝕刻或機械切割方式產生缺口51和52。此外,雖然在本實施例中所示之缺口51和52並不限制為圖式所示之形狀,其他形狀及圖案可構成隔離效果者亦可適用於本創作。此缺口面積以不超過單面總面積之25%較佳。In other words, the upper and lower surfaces of the PTC material layer 41 are respectively provided with a first conductive layer 42 and a second conductive layer 43, and each extends to the opposite side surfaces 61 and 62. The conductive layers 42, 43 may be formed by planar metal film films such as laser ablation, chemical etching or mechanical cutting to form notches 51 and 52. In addition, although the notches 51 and 52 shown in this embodiment are not limited to the shapes shown in the drawings, other shapes and patterns may constitute the isolation effect, and may be applied to the present creation. The notch area is preferably not more than 25% of the total area of one side.
PTC材料層41中含有高分子材料及導電粒子,而具有PTC特性。其適用之高分子材料包括:聚乙烯、聚丙烯、聚氟烯、前述之混合物及共聚合物等。導電粒子可為金屬粒子、含碳粒子、金屬氧化物、金屬碳化物,或是前述材料之混合物。The PTC material layer 41 contains a polymer material and conductive particles, and has PTC characteristics. Suitable polymer materials include polyethylene, polypropylene, polyfluoroolefin, the aforementioned mixtures and copolymers. The conductive particles may be metal particles, carbonaceous particles, metal oxides, metal carbides, or a mixture of the foregoing.
如習知技術所言,導電通孔太小可能因切割刀具偏移或外層線路對位偏移導致切割偏移的相關問題。因此,本創作之導電通孔48之孔徑(半徑)不能太小。一般以0603規格而言,導電通孔48的半徑約在0.18至0.23mm範圍。以0402規格而言,導電
通孔48的半徑約在0.11至0.16mm範圍。綜言之,導電通孔48不能太小,該四個導電通孔48的截面積總和佔該過電流保護元件40之形狀因數面積必須達一定比例以上。以形狀因數0603規格而言,若以半徑0.18mm計算,單個導電通孔48的截面積A1為(0.18mm×0.18mm×3.14)/4=0.025mm2
,故四個導電通孔48的截面積總和為0.025mm2
×4=0.1mm2
。0603的形狀因數面積A0為0.06英吋×0.03英吋=1.524mm×0.762mm=1.161mm2
。此時,四個導電通孔的截面積總和佔該過電流保護元件之形狀因數面積之比例(4×A1/A0)約9%(0.1 mm2
/1.161mm2
)。以同樣方式可計算不同形狀因數及不同導電通孔孔徑的4×A1/A0比例如下表1所示:
綜上,四個導電通孔的截面積總和佔該過電流保護元件之形狀因數面積之比例(4×A1/A0)約介於 7%~20%之間,或特別是在8%~18%範圍內。該4×A1/A0之值亦可為10%或15%。以0402規格而言,4×A1/A0之比例約介於7~16%。In summary, the sum of the cross-sectional areas of the four conductive vias accounts for the ratio of the shape factor area of the overcurrent protection component (4×A1/A0). Between 7% and 20%, or especially between 8% and 18%. The value of 4×A1/A0 can also be 10% or 15%. In terms of the 0402 specification, the ratio of 4×A1/A0 is about 7-16%.
從另一角度來看,本創作之導電通孔的總寬度2R於較短的側邊寬度W中佔有一定比例。以0603規格而言,較短的側邊寬度W為0.03英吋=0.762mm,若以導電通孔的半徑R為0.18mm計算,導電通孔的寬度總和佔側邊寬度的比例為2×R/W=2×0.18mm/0.762mm=47%。依同樣方式計算,可計算不同形狀因數及不同導電通孔孔徑的2×R/W比例如下表2所示,約在42~65%之間,或特別地為45%、50%或55%。From another point of view, the total width 2R of the conductive via of the present invention occupies a certain proportion in the shorter side width W. In the 0603 specification, the shorter side width W is 0.03 inch = 0.762 mm. If the radius R of the conductive via is 0.18 mm, the ratio of the width of the conductive via to the width of the side is 2 × R. /W = 2 x 0.18 mm / 0.762 mm = 47%. Calculated in the same way, the 2×R/W ratios of different form factors and different conductive via apertures can be calculated as shown in Table 2 below, about 42~65%, or especially 45%, 50% or 55%. .
參照圖6,因為導電通孔48位於相鄰側表面的轉角處,故元件40限制於軌道64中推進以進行相關檢測或包裝時,元件40之側表面61將抵靠相鄰元 件40之側表面62。相較於圖3B所示之情況,因過電流保護元件40側表面61和62中央處並無凹孔,即使導電通孔的寬度總和佔側邊寬度的比例超過一半,只要該比例小於等於65%,仍不會有如圖3B所示之不當推送和卡料的情況。Referring to Figure 6, because the conductive vias 48 are located at the corners of adjacent side surfaces, the side surface 61 of the component 40 will abut the adjacent element when the element 40 is constrained to advance in the track 64 for related detection or packaging. Side surface 62 of member 40. Compared with the case shown in FIG. 3B, there are no recesses in the center of the side surfaces 61 and 62 of the overcurrent protection element 40, even if the ratio of the total width of the conductive vias to the width of the side is more than half, as long as the ratio is 65 or less. %, there will still be no improper push and jam as shown in Figure 3B.
上述實施例係關於包含一個PTC材料層的情況,在實際應用上,其亦可包含多層並聯之PTC材料層。例如美國專利號US 6,377,467所示之二層並聯PTC結構,但必須將導電通孔設於側表面之轉角處,另外導電通孔佔形狀因數之比例必須符合本創作界定之數值範圍。The above embodiment relates to the case of including a layer of PTC material, and in practical applications, it may also comprise a plurality of layers of PTC material in parallel. For example, the two-layer parallel PTC structure shown in U.S. Patent No. 6,377,467, but the conductive vias must be disposed at the corners of the side surfaces, and the ratio of the conductive vias to the form factor must conform to the numerical range defined by this creation.
根據本創作之設計,過電流保護元件可允許製作較大的導電通孔,進而提供元件進行切粒時較大之容差,且在外觀檢測、電阻量測及包裝時不致產生卡料等情況。因此,本創作不僅可提升生產速度,且對於生產良率亦有一定助益。According to the design of the present invention, the overcurrent protection component allows for the production of larger conductive vias, thereby providing a larger tolerance for component dicing, and does not cause jamming during appearance inspection, resistance measurement, and packaging. . Therefore, this creation not only improves production speed, but also contributes to production yield.
本創作之技術內容及技術特點已揭示如上,然而本領域具有通常知識之技術人士仍可能基於本創作之教示及揭示而作種種不背離本創作精神之替換及修飾。因此,本創作之保護範圍應不限於實施例所揭示者,而應包括各種不背離本創作之替換及修飾,並為以下之申請專利範圍所涵蓋。The technical content and technical features of the present invention have been disclosed as above, but those skilled in the art can still make various substitutions and modifications without departing from the spirit of the present invention based on the teachings and disclosures of the present invention. Therefore, the scope of the present invention is not limited to the embodiments disclosed, but includes various alternatives and modifications that do not depart from the present invention and are covered by the following claims.
10、40‧‧‧過電流保護元件10, 40‧‧‧Overcurrent protection components
11‧‧‧電阻元件11‧‧‧Resistive components
12‧‧‧高分子材料層12‧‧‧ Polymer layer
13‧‧‧第一導電構件13‧‧‧First conductive member
14‧‧‧第二導電構件14‧‧‧Second conductive member
15、16‧‧‧絕緣層15, 16‧‧‧Insulation
17‧‧‧第一電極17‧‧‧First electrode
18‧‧‧第二電極18‧‧‧second electrode
19‧‧‧第一導電通孔19‧‧‧First conductive via
20‧‧‧第二導電通孔20‧‧‧Second conductive via
21‧‧‧防焊層21‧‧‧ solder mask
24‧‧‧軌道24‧‧‧ Track
41‧‧‧PTC材料層41‧‧‧ PTC material layer
42‧‧‧第一導電層42‧‧‧First conductive layer
43‧‧‧第二導電層43‧‧‧Second conductive layer
44‧‧‧第一絕緣層44‧‧‧First insulation
45‧‧‧第二絕緣層45‧‧‧Second insulation
46‧‧‧第一電極層46‧‧‧First electrode layer
47‧‧‧第二電極層47‧‧‧Second electrode layer
48‧‧‧導電通孔48‧‧‧Electrical through holes
51‧‧‧第一缺口51‧‧‧ first gap
52‧‧‧第二缺口52‧‧‧ second gap
53‧‧‧第一防焊層53‧‧‧First solder mask
54‧‧‧第二防焊層54‧‧‧Second solder mask
61‧‧‧第一側表面61‧‧‧First side surface
62‧‧‧第二側表面62‧‧‧Second side surface
64‧‧‧軌道64‧‧‧ Track
411‧‧‧第一表面411‧‧‧ first surface
412‧‧‧第二表面412‧‧‧ second surface
461‧‧‧第一金屬箔461‧‧‧First metal foil
471‧‧‧第二金屬箔471‧‧‧Second metal foil
圖1繪示習知之過電流保護元件之立體示意圖。FIG. 1 is a schematic perspective view of a conventional overcurrent protection component.
圖2A及2B繪示習知之過電流保護元件進行切割時之示意圖。2A and 2B are schematic views showing a conventional overcurrent protection element when it is cut.
圖3A及3B繪示習知之過電流保護元件製作過程之示意圖。3A and 3B are schematic diagrams showing a process of fabricating a conventional overcurrent protection device.
圖4A至4C繪示本創作一實施例之過電流保護元件示意圖。4A to 4C are schematic diagrams showing an overcurrent protection component of an embodiment of the present invention.
圖5繪示本創作之過電流保護元件之形狀因數和導電通孔之關係示意圖。FIG. 5 is a schematic diagram showing the relationship between the form factor and the conductive via of the overcurrent protection device of the present invention.
圖6繪示本創作一實施例之過電流保護元件製作過程之示意圖。FIG. 6 is a schematic diagram showing a process of fabricating an overcurrent protection component according to an embodiment of the present invention.
40‧‧‧過電流保護元件40‧‧‧Overcurrent protection components
41‧‧‧PTC材料層41‧‧‧ PTC material layer
42‧‧‧第一導電層42‧‧‧First conductive layer
43‧‧‧第二導電層43‧‧‧Second conductive layer
44‧‧‧第一絕緣層44‧‧‧First insulation
45‧‧‧第二絕緣層45‧‧‧Second insulation
46‧‧‧第一電極層46‧‧‧First electrode layer
47‧‧‧第二電極層47‧‧‧Second electrode layer
48‧‧‧導電通孔48‧‧‧Electrical through holes
51、52‧‧‧缺口51, 52‧‧ ‧ gap
53、54‧‧‧防焊層53, 54‧‧‧ solder mask
61‧‧‧第一側表面61‧‧‧First side surface
62‧‧‧第二側表面62‧‧‧Second side surface
411‧‧‧第一表面411‧‧‧ first surface
412‧‧‧第二表面412‧‧‧ second surface
461‧‧‧第一金屬箔461‧‧‧First metal foil
471‧‧‧第二金屬箔471‧‧‧Second metal foil
Claims (12)
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TW101214856U TWM446416U (en) | 2012-07-31 | 2012-07-31 | Over-current protection device |
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TW101214856U TWM446416U (en) | 2012-07-31 | 2012-07-31 | Over-current protection device |
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TWI449061B (en) * | 2012-07-31 | 2014-08-11 | Polytronics Technology Corp | Over-current protection device |
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TWI449061B (en) * | 2012-07-31 | 2014-08-11 | Polytronics Technology Corp | Over-current protection device |
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