TW201349959A - Flexible printed circuit module - Google Patents
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Abstract
Description
本發明係關於一種可撓性電路模組。 The present invention relates to a flexible circuit module.
可撓性電路板已廣泛利用於日益薄型化、小型化的各種電子裝置。以液晶顯示模組為例,顯示面板與背光單元之間即藉由可撓性電路板電性連接。另外,可撓性電路板通常係利用導電膠將其導電金屬層貼附於液晶顯示模組的背板而接地。 Flexible circuit boards have been widely used in various electronic devices that are increasingly thinner and smaller. Taking a liquid crystal display module as an example, the display panel and the backlight unit are electrically connected by a flexible circuit board. In addition, the flexible circuit board is usually grounded by attaching a conductive metal layer to the back plate of the liquid crystal display module by using a conductive adhesive.
然而,不同的可撓性電路板係因材質、厚度、製程相異而會有不同的柔軟性。進行將可撓性電路板貼附於液晶顯示模組的背板的加工時,即使施加相同的應力,亦有可能因可撓性電路板的柔軟性不同造成應力集中於可撓性電路板上的受力點而導致可撓性電路板不平整。特別是重工時,被撕起的可撓性電路板通常呈皺摺、翹曲或捲曲狀態,欲將呈皺摺、翹曲或捲曲狀態的可撓性電路板重新貼附於液晶顯示模組的背板時,變形的應力則會集中於皺摺、翹曲或捲曲的部份。如圖7所示,由可撓性基板200、導電金屬層300’、以及第一絕緣層400所構成的可撓性電路板於重工時呈翹曲狀態。欲於電子裝置900的背板預定位置910重新以導電膠920貼附裸露區域410的導電金屬層300’時,因應力集中於翹曲的部分使得如此的可撓性電路板難以平整地貼附,造成導電金屬層300’與電子裝置900之間 的有效接觸面積變小,進而增加導電金屬層300’與電子裝置900之間的接觸阻抗,影響可撓性電路板的接地效果。 However, different flexible circuit boards have different flexibility depending on materials, thickness, and process. When the flexible circuit board is attached to the back sheet of the liquid crystal display module, even if the same stress is applied, the stress may be concentrated on the flexible circuit board due to the difference in flexibility of the flexible circuit board. The force point causes the flexible circuit board to be uneven. Especially in heavy work, the torn flexible circuit board is usually wrinkled, warped or curled, and the flexible circuit board in a wrinkled, warped or curled state is reattached to the liquid crystal display module. The deformation stress is concentrated on the wrinkled, warped or curled portion of the backsheet. As shown in Fig. 7, the flexible circuit board composed of the flexible substrate 200, the conductive metal layer 300', and the first insulating layer 400 is warped at the time of rework. When the conductive metal layer 300 ′ of the bare region 410 is reattached with the conductive paste 920 at the predetermined position 910 of the back plate of the electronic device 900, it is difficult to flatten such a flexible circuit board due to stress concentrated on the warped portion. Between the conductive metal layer 300' and the electronic device 900 The effective contact area becomes small, thereby increasing the contact resistance between the conductive metal layer 300' and the electronic device 900, affecting the grounding effect of the flexible circuit board.
對此,本發明係提供一種可撓性電路模組,可增加可撓性電路板一部分的柔軟性,將集中於可撓性電路板上呈皺摺、翹曲或捲曲部分的應力分散,使可撓性電路板容易平整貼附。 In view of the above, the present invention provides a flexible circuit module which can increase the flexibility of a part of the flexible circuit board and distribute the stress concentrated in the wrinkled, warped or curled portion of the flexible circuit board. The flexible circuit board is easy to attach flat.
另外,本發明係提供一種可撓性電路模組,藉由增加導電膠和導電金屬層的裸露區域之間的接觸面積,可減少可撓性電路板的導電金屬層與其貼附的導體之間的接觸阻抗,進而改善導電效率。 In addition, the present invention provides a flexible circuit module which can reduce the contact area between the conductive metal layer of the flexible circuit board and the attached conductor by increasing the contact area between the conductive paste and the exposed area of the conductive metal layer. Contact resistance, which in turn improves electrical conductivity.
為了達成上述目的,本發明係提供一種可撓性電路模組,其包含具有第一面的可撓性基板;舖設於第一面上的第一導電金屬層;以及舖設於部分第一導電金屬層上,以使部分第一導電金屬層裸露的第一絕緣層。其中裸露的第一導電金屬層包含一接地墊,其具有交錯設置之複數個穿孔部及凸起部。 In order to achieve the above object, the present invention provides a flexible circuit module including a flexible substrate having a first surface; a first conductive metal layer disposed on the first surface; and a portion of the first conductive metal a first insulating layer on the layer to expose a portion of the first conductive metal layer. The bare first conductive metal layer comprises a ground pad having a plurality of perforated portions and protrusions arranged in a staggered manner.
另外,本發明係提供一種可撓性電路模組,其包含具有第一面的可撓性基板;舖設於第一面上的第一導電金屬層;以及舖設於部分第一導電金屬層上,以使部分第一導電金屬層裸露的第一絕緣層。其中裸露的第一導電金屬層包含一接地墊,其具有複數個穿孔部及分別圍繞該些穿孔部的環形凸起部。此時,該些環形凸起部之內壁可圍成該些穿孔部。 In addition, the present invention provides a flexible circuit module including a flexible substrate having a first surface, a first conductive metal layer disposed on the first surface, and a portion of the first conductive metal layer. a first insulating layer that exposes a portion of the first conductive metal layer. The bare first conductive metal layer comprises a ground pad having a plurality of perforations and annular protrusions respectively surrounding the perforations. At this time, the inner walls of the annular protrusions may surround the perforations.
該些穿孔部之直徑可介於0.01毫米(mm)至0.3毫米(mm)之間,而複數個穿孔部之總合底面面積與該裸露的第一導電金屬層面積之比值,可介於0.01至0.5之間,較佳係介於0.1至0.5之間,而以介於0.25至0.5之間為更佳。 The diameter of the perforated portion may be between 0.01 mm (mm) and 0.3 mm (mm), and the ratio of the total bottom surface area of the plurality of perforated portions to the exposed first conductive metal layer area may be between 0.01 Between 0.5 and 0.5, preferably between 0.1 and 0.5, and more preferably between 0.25 and 0.5.
裸露的第一導電金屬層可電性連接於電子裝置的預定位置。此預定位置可為金屬殼體、防護接地電路、或者預定的電路配線。 The exposed first conductive metal layer can be electrically connected to a predetermined position of the electronic device. This predetermined position may be a metal casing, a protective ground circuit, or a predetermined circuit wiring.
本發明之可撓性電路模組可更包含舖設於可撓性基板相對於第一面之一第二面上的第二導電金屬層。此時,穿孔部可貫穿第一導電金屬層、可撓性基板、以及第二導電金屬層。第二導電金屬層上可更舖設第二絕緣層。對應可撓性電路模組的電路配線設計,可於穿孔部內設置導電材料電性連接第一導電金屬層與第二導電金屬層。 The flexible circuit module of the present invention may further comprise a second conductive metal layer disposed on the second surface of the flexible substrate relative to the first surface. At this time, the through portion may penetrate the first conductive metal layer, the flexible substrate, and the second conductive metal layer. A second insulating layer may be further disposed on the second conductive metal layer. Corresponding to the circuit wiring design of the flexible circuit module, a conductive material may be electrically connected to the first conductive metal layer and the second conductive metal layer in the through hole portion.
另外,本發明係提供一種電子裝置,其係包含上述可撓性電路模組;金屬殼體;以及位於可撓性電路模組與金屬殼體之間,電性連接裸露的第一導電金屬層與金屬殼體的導電膠。此時,電子裝置可進一步包含防護接地電路,第一導電金屬層係電性連接於防護接地電路。 In addition, the present invention provides an electronic device including the above flexible circuit module, a metal case, and a first conductive metal layer electrically connected between the flexible circuit module and the metal case. Conductive adhesive with a metal casing. At this time, the electronic device may further include a protective ground circuit, and the first conductive metal layer is electrically connected to the protective ground circuit.
另外,導電膠可填充進入該些穿孔部內。導電膠亦可包覆該些凸起部。 In addition, a conductive paste can be filled into the perforations. The conductive paste may also cover the protrusions.
圖1係本發明之可撓性電路模組一實施型態的俯視圖。圖2係圖1中沿AA方向的斷面示意圖。如圖1、圖2 所示,可撓性電路模組100係於可撓性基板200的第一面210上舖設第一導電金屬層300,再於部分第一導電金屬層300上舖設第一絕緣層400,而未舖設第一絕緣層400之第一導電金屬層300則形成裸露區域410,裸露的第一導電金屬層300例如為可撓性電路模組100之接地墊。可撓性電路模組100之裸露區域410係與電子裝置900的預定位置910(例如電子裝置900上的金屬殼體、防護接地電路等的預定位置910)相對應貼附。第一導電金屬層300裸露於裸露區域410的部分中具有交錯設置之複數個穿孔部330及凸起部340。交錯設置之型態可如圖1所示的等間隔方眼矩陣型態但不限於此。 1 is a plan view showing an embodiment of a flexible circuit module of the present invention. Figure 2 is a schematic cross-sectional view taken along line AA of Figure 1. As shown in Figure 1, Figure 2 As shown, the flexible circuit module 100 is disposed on the first surface 210 of the flexible substrate 200, and the first conductive layer 400 is disposed on the portion of the first conductive metal layer 300. The first conductive metal layer 300 of the first insulating layer 400 is formed to form a bare region 410. The exposed first conductive metal layer 300 is, for example, a ground pad of the flexible circuit module 100. The exposed area 410 of the flexible circuit module 100 is attached to a predetermined position 910 of the electronic device 900 (eg, a predetermined position 910 of a metal housing, a protective ground circuit, etc. on the electronic device 900). The portion of the first conductive metal layer 300 exposed in the bare region 410 has a plurality of perforated portions 330 and protrusions 340 interlaced. The type of the interlaced arrangement may be an equally spaced square matrix type as shown in FIG. 1 but is not limited thereto.
此型態的可撓性電路模組100的製作,首先將可撓性基板200與導電金屬層(未繪示)疊層後,藉由蝕刻、微影等加工法,形成預定電路圖樣的第一導電金屬層300。接著,第一絕緣層400疊層於第一導電金屬層300上方,藉由蝕刻、微影等加工法,圖案化第一絕緣層400以形成裸露區域410,使第一導電金屬層300的一部分裸露。之後,於裸露的第一導電金屬層300的位置,形成穿孔部330與凸起部340。穿孔部330可藉由蝕刻、棒針放電加工、沖孔、鑽孔等習用的加工法進行加工製作。製作穿孔部330時,以沖孔、鑽孔的方法可製作出貫穿可撓性基板200及第一導電金屬層300的穿孔部330。如此的穿孔部330可使可撓性基板200及第一導電金屬層300的部分皆鏤空,增加柔軟性而較佳。但亦可利用蝕刻、棒針放電加工的方 法,僅於第一導電金屬層300形成穿孔部330。凸起部340的製作,可藉由模具沖壓、鍍金屬、金屬沉積等習用的加工法進行加工。 In the fabrication of the flexible circuit module 100 of this type, first, the flexible substrate 200 is laminated with a conductive metal layer (not shown), and then a predetermined circuit pattern is formed by etching or lithography. A conductive metal layer 300. Next, the first insulating layer 400 is stacked on the first conductive metal layer 300, and the first insulating layer 400 is patterned by etching, lithography or the like to form the exposed region 410, so that a part of the first conductive metal layer 300 is formed. bare. Thereafter, the perforated portion 330 and the raised portion 340 are formed at the position of the exposed first conductive metal layer 300. The perforated portion 330 can be processed by a conventional processing method such as etching, rod discharge machining, punching, drilling, and the like. When the perforated portion 330 is formed, the perforated portion 330 penetrating the flexible substrate 200 and the first conductive metal layer 300 can be formed by punching or drilling. Such a perforated portion 330 can hollow out portions of the flexible substrate 200 and the first conductive metal layer 300 to increase flexibility. However, it is also possible to use etching and rod discharge machining. In the method, the perforated portion 330 is formed only in the first conductive metal layer 300. The formation of the raised portion 340 can be processed by conventional processing methods such as die stamping, metal plating, and metal deposition.
該些穿孔部330之直徑可介於0.01毫米(mm)至0.3毫米(mm)之間,而位於同裸露區域410中的複數個穿孔部330的總合面積與同裸露區域410面積之比值,可介於0.01至0.5之間,較佳係介於0.1至0.5之間,而以介於0.25至0.5之間為更佳。 The diameter of the perforated portion 330 may be between 0.01 millimeters (mm) and 0.3 millimeters (mm), and the ratio of the total area of the plurality of perforated portions 330 in the same exposed area 410 to the area of the exposed area 410, It may be between 0.01 and 0.5, preferably between 0.1 and 0.5, and more preferably between 0.25 and 0.5.
藉由上述的位於同裸露區域410中的複數個穿孔部330、複數個凸起部340,與同裸露區域410之間的面積的比值關係,以及穿孔部330之直徑範圍,可對應設定適當的穿孔部330、凸起部340的數量以及穿孔部330的直徑。 The ratio of the ratio of the area between the plurality of perforated portions 330 and the plurality of raised portions 340 in the same exposed area 410 to the area of the exposed area 410 and the diameter of the perforated portion 330 can be appropriately set. The number of the perforated portion 330, the raised portion 340, and the diameter of the perforated portion 330.
圖3係表示本發明之可撓性電路模組進行重工貼附的示意圖。如圖7所示,習用之可撓性電路板因重工被撕起時會呈皺摺、翹曲或捲曲狀態,欲將呈皺摺、翹曲或捲曲狀態的可撓性電路板重新貼附於電子裝置900(例如液晶顯示模組)的背板預定位置910時,變形的應力集中於皺摺、翹曲或捲曲的部份,難以平整貼附。然而,如圖3所示,本發明的可撓性電路模組100可藉由穿孔部330的設置,使裸露於裸露區域410的第一導電金屬層300因一部分鏤空而增加柔軟性,藉此,相較於圖7,將集中於皺摺、翹曲或捲曲部份的應力分散,重新貼附於電子裝置900(例如液晶顯示模組)的背板預定位置910時,容易平整貼附。藉此,裸露的第一導電金屬層300之接地墊與電子裝置900 (例如液晶顯示模組)的背板預定位置910之間的接觸阻抗減少,可改善導電效率,進而改善接地的效果。 Fig. 3 is a schematic view showing the attachment of the flexible circuit module of the present invention to the rework. As shown in FIG. 7, the conventional flexible circuit board is wrinkled, warped or curled when the heavy work is torn, and the flexible circuit board in a wrinkled, warped or curled state is to be reattached. When the back plate of the electronic device 900 (for example, a liquid crystal display module) is at a predetermined position 910, the stress of deformation is concentrated on the wrinkled, warped or curled portion, and it is difficult to flatten the attachment. However, as shown in FIG. 3, the flexible circuit module 100 of the present invention can increase the flexibility of the first conductive metal layer 300 exposed to the exposed region 410 by a portion of the hollow portion by the provision of the through-hole portion 330. Compared with FIG. 7, when the stress concentrated on the wrinkles, warps, or curled portions is dispersed and reattached to the predetermined position 910 of the back sheet of the electronic device 900 (for example, a liquid crystal display module), it is easy to flatten and attach. Thereby, the ground pad of the exposed first conductive metal layer 300 and the electronic device 900 The contact resistance between the predetermined positions 910 of the backplane (for example, the liquid crystal display module) is reduced, and the conductive efficiency can be improved, thereby improving the grounding effect.
圖4係本發明之可撓性電路模組另一實施型態的俯視圖。圖5係圖4中沿BB方向的斷面示意圖。圖4、圖5所示的可撓性電路模組110與圖1、圖2所示的可撓性電路模組100相異處僅在於穿孔部、凸起部的型態,另外,圖4、圖5所示的可撓性電路模組110係凸起部朝上而繪示,並且,圖4中以斜線陰影表示凸起部以明顯標示凸起部的型態,實際的製品並無如此的表示。以下僅說明此相異處而省略其他部分的詳細說明。 4 is a plan view showing another embodiment of the flexible circuit module of the present invention. Figure 5 is a schematic cross-sectional view taken along line BB of Figure 4. The flexible circuit module 110 shown in FIG. 4 and FIG. 5 differs from the flexible circuit module 100 shown in FIG. 1 and FIG. 2 only in the form of the perforated portion and the convex portion. In addition, FIG. 4 The flexible circuit module 110 shown in FIG. 5 is shown with the convex portion facing upward, and the convex portion is indicated by oblique hatching in FIG. 4 to clearly indicate the shape of the convex portion, and the actual product is not Such an expression. Only the details of this difference will be described below, and the detailed description of the other parts will be omitted.
如圖4、圖5所示,裸露區域410中具有複數個穿孔部330及分別圍繞該些穿孔部330的環形凸起部341。 As shown in FIG. 4 and FIG. 5 , the exposed area 410 has a plurality of perforated portions 330 and annular protrusions 341 respectively surrounding the perforated portions 330 .
此型態的穿孔部330與環形凸起部341的製作,可如同上述實施型態,疊層可撓性基板200、第一導電金屬層300、以及第一絕緣層400,並於第一絕緣層400的預定位置形成裸露區域410之後,藉由棒針模具於裸露區域410的位置從可撓性基板200往第一導電金屬層300的方向沖壓,以棒針模具頂穿可撓性基板200及第一導電金屬層300,即於第一導電金屬層300的預定位置形成穿孔部330,並且,因棒針模具沖壓第一導電金屬層300形成穿孔部330的同時,第一導電金屬層300會於穿孔部330的周圍產生毛刺凸起,此即形成環形凸起部341,相對地,環形凸起部341之內壁圍成該些穿孔部330。如此,僅需單一製程以及單一工作機即可同時形成穿孔部330與環形凸 起部341,可藉以縮短製程,減少製作成本。 The perforated portion 330 and the annular convex portion 341 of the present type can be fabricated as in the above embodiment, and the flexible substrate 200, the first conductive metal layer 300, and the first insulating layer 400 are laminated, and the first insulating layer is insulated. After the predetermined position of the layer 400 is formed into the exposed region 410, the position of the exposed portion 410 is pressed from the flexible substrate 200 toward the first conductive metal layer 300 by the bar mold, and the flexible substrate 200 is passed through the rod mold. A conductive metal layer 300, that is, a through-hole portion 330 is formed at a predetermined position of the first conductive metal layer 300, and the first conductive metal layer 300 is perforated while the first conductive metal layer 300 is formed by the bar mold to form the through-hole portion 330. A burr protrusion is formed around the portion 330, which forms an annular projection 341, and the inner wall of the annular projection 341 encloses the perforated portion 330. In this way, the perforated portion 330 and the annular convex can be simultaneously formed by a single process and a single working machine. The starting portion 341 can shorten the manufacturing process and reduce the manufacturing cost.
上述實施型態中係以圓柱形的棒針模具進行沖壓,使得複數個環形凸起部341係呈圓環狀,分別圍繞於複數個穿孔部330,但不限於此,例如,以徑向斷面呈三角形或多邊形,或者其他徑向斷面形狀的棒針模具進行沖壓時,可對應地形成各種形狀的穿孔部330與圍繞於該當穿孔部330的環形凸起部341。 In the above embodiment, the cylindrical pin mold is pressed, so that the plurality of annular protrusions 341 are annular, respectively surrounding the plurality of perforated portions 330, but are not limited thereto, for example, in a radial section. When the bar needle mold having a triangular shape or a polygonal shape or other radial sectional shape is punched, the perforated portion 330 of various shapes and the annular convex portion 341 surrounding the perforated portion 330 may be correspondingly formed.
圖6係本發明之可撓性電路模組另一實施型態的斷面示意圖。如圖6所示,本實施型態中,於可撓性基板200的第一面210舖設第一導電金屬層300,並於可撓性基板200相對於第一面210之第二面220舖設第二導電金屬層500。於上述導電金屬層300、500形成預定電路圖樣之後,更於第一導電金屬層300上舖設第一絕緣層400以於第一絕緣層400的預定位置形成裸露區域410,並於第二導電金屬層500上舖設第二絕緣層600。之後,藉由棒針模具從絕緣層600往第一導電金屬層300的方向沖壓,形成貫穿絕緣層600、第二導電金屬層500、可撓性基板200、以及第一導電金屬層300的穿孔部330,並同時於第一導電金屬層300形成環形凸起部341,形成可撓性電路模組120。 Fig. 6 is a schematic cross-sectional view showing another embodiment of the flexible circuit module of the present invention. As shown in FIG. 6 , in the embodiment, the first conductive metal layer 300 is laid on the first surface 210 of the flexible substrate 200 , and is laid on the second surface 220 of the flexible substrate 200 relative to the first surface 210 . The second conductive metal layer 500. After the conductive metal layers 300, 500 are formed into a predetermined circuit pattern, the first insulating layer 400 is further disposed on the first conductive metal layer 300 to form a bare region 410 at a predetermined position of the first insulating layer 400, and is formed on the second conductive metal. A second insulating layer 600 is laid on the layer 500. Thereafter, punching is performed from the insulating layer 600 toward the first conductive metal layer 300 by a bar mold to form a through-hole of the insulating layer 600, the second conductive metal layer 500, the flexible substrate 200, and the first conductive metal layer 300. 330, and at the same time forming an annular convex portion 341 on the first conductive metal layer 300 to form the flexible circuit module 120.
此時,因穿孔部330貫穿絕緣層600、第二導電金屬層500、可撓性基板200、以及第一導電金屬層300,藉此,可使對應於裸露區域410的絕緣層600、第二導電金屬層500、可撓性基板200、以及第一導電金屬層300因一部分鏤空而增加柔軟性,使可撓性電路模組120容易平整貼 附。另外,對應可撓性電路模組120的電路配線設計,可於穿孔部330內壁,藉由電鍍、化學鍍、點膠等方法,填設導電材料700,藉以電性連接第一導電金屬層300與第二導電金屬層500,並且依舊保持穿孔部330的貫穿。 At this time, since the perforated portion 330 penetrates through the insulating layer 600, the second conductive metal layer 500, the flexible substrate 200, and the first conductive metal layer 300, the insulating layer 600 corresponding to the exposed region 410 and the second portion can be made thereby. The conductive metal layer 500, the flexible substrate 200, and the first conductive metal layer 300 are softened by a part of hollowing, so that the flexible circuit module 120 is easily flattened. Attached. In addition, corresponding to the circuit wiring design of the flexible circuit module 120, the conductive material 700 may be filled on the inner wall of the perforated portion 330 by electroplating, electroless plating, dispensing, etc., thereby electrically connecting the first conductive metal layer. 300 and the second conductive metal layer 500, and still maintain the penetration of the perforated portion 330.
量測可撓性電路模組與金屬殼體910之間的阻抗值,與未設有複數穿孔部及凸起部之一般的可撓性電路模組進行比較,未設有複數穿孔部及凸起部之一般的可撓性電路模組與金屬殼體910之間的平均阻抗值約為3.2 Ω。然而,本發明之可撓性電路模組100由於增加導電膠920和第一導電金屬層300的裸露區域410之間的接觸面積,量測可撓性電路模組100與金屬殼體910之間的阻抗值時所測得的阻抗值如下表所示。 Comparing the impedance value between the flexible circuit module and the metal casing 910, compared with a general flexible circuit module not provided with a plurality of perforated portions and raised portions, no plural perforated portions and convex portions are provided The average impedance between the general flexible circuit module and the metal housing 910 of the starting portion is about 3.2 Ω. However, the flexible circuit module 100 of the present invention measures the contact area between the conductive adhesive 920 and the exposed region 410 of the first conductive metal layer 300, and measures between the flexible circuit module 100 and the metal housing 910. The impedance values measured at the impedance values are shown in the table below.
(面積比值係指穿孔部之總合面積與該裸露區域面積之比值) (Area ratio refers to the ratio of the total area of the perforated portion to the area of the exposed area)
如此表所示,藉由本發明的可撓性電路模組可減少可撓性電路模組的導電金屬層與其貼附的導體之間的接觸阻抗,改善導電效率,且可得知在穿孔部330之直徑可介於 0.01毫米(mm)至0.3毫米(mm)之間,而位於同裸露區域410中的複數個穿孔部330的總合面積與同裸露區域410面積之比值,可介於0.01至0.5之間,當穿孔部330之直徑及面積比值愈大,導電膠920和第一導電金屬層300的裸露區域410之間的接觸面積越大,降低接觸阻抗效果越佳。依上述實驗結果,同裸露區域410的穿孔部330與第一導電金屬層300之間的面積比值為0.5時,降低接觸阻抗效果優於比值為0.01,然而,若上述比值超過0.5時,於裸露區域410中,作為導體的第一導電金屬層300減少至一定程度,若為如此的情況時,因導體的減少,反而無益於降低接觸阻抗,因此,同裸露區域410的穿孔部330與第一導電金屬層300之間的面積比值,以不超過0.5為較佳。 As shown in the table, the flexible circuit module of the present invention can reduce the contact resistance between the conductive metal layer of the flexible circuit module and the conductor to which it is attached, improve the conduction efficiency, and can be known in the perforated portion 330. The diameter can be between Between 0.01 mm (mm) and 0.3 mm (mm), and the ratio of the total area of the plurality of perforated portions 330 in the same exposed area 410 to the area of the exposed area 410 may be between 0.01 and 0.5. The larger the ratio of the diameter to the area of the perforated portion 330, the larger the contact area between the conductive paste 920 and the exposed region 410 of the first conductive metal layer 300, and the better the effect of reducing the contact resistance. According to the above experimental results, when the area ratio between the perforated portion 330 of the bare region 410 and the first conductive metal layer 300 is 0.5, the effect of lowering the contact resistance is better than the ratio of 0.01, however, if the ratio exceeds 0.5, the bare ratio is exposed. In the region 410, the first conductive metal layer 300 as a conductor is reduced to a certain extent. If this is the case, the contact resistance is not favored due to the reduction of the conductor, and therefore, the perforated portion 330 of the same exposed region 410 and the first The area ratio between the conductive metal layers 300 is preferably not more than 0.5.
如圖所示,將上述各實施型態的可撓性電路模組100、110、120應用於電子裝置時,可撓性電路模組可藉由導電膠920,以裸露的第一導電金屬層300與電子裝置的預定位置910電性連接,此預定位置可為金屬殼體、防護接地電路、預定的電路配線等等。施加應力將可撓性電路模組貼附於電子裝置時,藉由穿孔部330分散使可撓性電路模組皺摺、翹曲或捲曲的應力,以平坦地將可撓性電路模組貼附於電子裝置,又因壓力的施加,導電膠920係填充進入穿孔部330內並且包覆凸起部340、341。藉此,增加導電膠920與第一導電金屬層300之間的接觸面積,減少第一導電金屬層300與預定位置910之間的接觸阻抗,進而 改善可撓性電模組的接地效果。 As shown in the figure, when the flexible circuit modules 100, 110, and 120 of the above embodiments are applied to an electronic device, the flexible circuit module can be exposed to the first conductive metal layer by the conductive adhesive 920. The 300 is electrically connected to a predetermined position 910 of the electronic device, and the predetermined position may be a metal casing, a protective ground circuit, a predetermined circuit wiring, or the like. When the flexible circuit module is attached to the electronic device by applying stress, the flexible circuit module is flatly pasted by the stress of wrinkling, warping or curling the flexible circuit module by the punching portion 330 Attached to the electronic device, and due to the application of pressure, the conductive paste 920 is filled into the perforated portion 330 and covers the raised portions 340, 341. Thereby, the contact area between the conductive paste 920 and the first conductive metal layer 300 is increased, and the contact resistance between the first conductive metal layer 300 and the predetermined position 910 is reduced, thereby further Improve the grounding effect of the flexible electrical module.
上述可撓性電路模組100的特徵係改變裸露區域410中的裸露的第一導電金屬層300的型態,於裸露區域中的導電金屬層交錯設置複數穿孔部及凸起部。可撓性電路模組110係可撓性電路模組100的變化實施,其特徵係改變穿孔部及凸起部的形態,以單一製程以及單一工作機同時形成穿孔部與環形凸起部,藉以縮短製程,減少製作成本。 The flexible circuit module 100 is characterized in that the shape of the exposed first conductive metal layer 300 in the exposed region 410 is changed, and the plurality of perforated portions and the raised portions are alternately arranged in the conductive metal layer in the exposed region. The flexible circuit module 110 is a modified implementation of the flexible circuit module 100. The feature is that the shape of the perforated portion and the convex portion are changed, and the perforated portion and the annular convex portion are simultaneously formed by a single process and a single working machine. Shorten the process and reduce production costs.
可撓性電路模組120更將穿孔部與環形凸起部應用於多層可撓性電路板中,可撓性電路模組120中揭示包含二導電金屬層300、500的實施型態,但不限於此,對應實際的電路設計,可撓性電路模組120可包含複數層的導電金屬層。 The flexible circuit module 120 further applies the perforated portion and the annular convex portion to the multi-layer flexible circuit board. The flexible circuit module 120 discloses an embodiment including the two conductive metal layers 300 and 500, but To be limited thereto, the flexible circuit module 120 may include a plurality of layers of conductive metal layers corresponding to actual circuit designs.
此外,可撓性電路模組100、110、120中的可撓性基板200、各導電金屬層300、500、以及各絕緣層400、600可採用習用之材料,以習用之方法製作,在此不再贅述。 In addition, the flexible substrate 200, the conductive metal layers 300, 500, and the insulating layers 400, 600 of the flexible circuit modules 100, 110, and 120 can be fabricated by conventional methods using conventional materials. No longer.
上述各實施型態中僅以對應於一裸露區域410中的導電金屬層300、500進行說明,但不限於此,亦可於一可撓性電路模組設置複數個裸露區域,並分別於各裸露區域對應的導電金屬層交錯設置複數個穿孔部及凸起部。 In the above embodiments, only the conductive metal layers 300 and 500 corresponding to a bare region 410 are described. However, the present invention is not limited thereto, and a plurality of bare regions may be disposed in a flexible circuit module, and respectively A plurality of perforated portions and raised portions are alternately arranged in the conductive metal layers corresponding to the bare regions.
另外,上述製作各可撓性電路模組100、110、120的實施型態中已分別舉例說明一製作步驟,但製作步驟不限於此,只要製品的最終型態為裸露於第一絕緣層400的第一導電金屬層300的部分上形成穿孔部330與凸起部340、341,可依製作上的需求,變更製作步驟,例如上述各實施 型態以先形成裸露區域410之後再形成穿孔部330、凸起部340、341進行說明,但亦可先形成穿孔部330、凸起部340、341之後,再對應穿孔部330、凸起部340、341的位置形成裸露區域410。 In addition, a manufacturing step has been separately illustrated in the above embodiments for fabricating each of the flexible circuit modules 100, 110, and 120, but the manufacturing steps are not limited thereto, as long as the final pattern of the product is exposed to the first insulating layer 400. The portion of the first conductive metal layer 300 is formed with a perforated portion 330 and raised portions 340, 341, which can be modified according to the needs of the production, such as the above implementations. The description will be made by forming the exposed portion 410 and then forming the perforated portion 330 and the convex portions 340 and 341. However, the perforating portion 330 and the convex portions 340 and 341 may be formed first, and then the perforating portion 330 and the convex portion may be correspondingly formed. The locations of 340, 341 form a bare area 410.
上述說明中例舉液晶顯示模組進行說明,但本發明的應用不限於此而可於採用可撓性電路模組的各種裝置中廣泛應用。 Although the liquid crystal display module is described in the above description, the application of the present invention is not limited thereto, and can be widely applied to various devices using the flexible circuit module.
如上所述,藉由本發明的可撓性電路模組,即可增加可撓性電路模組一部分的柔軟性,將集中於可撓性電路模組上呈皺摺、翹曲或捲曲部分的應力分散,使可撓性電路模組容易平整貼附,並且,可減少可撓性電路模組的導電金屬層與其貼附的導體之間的接觸阻抗,改善導電效率。 As described above, with the flexible circuit module of the present invention, the flexibility of a part of the flexible circuit module can be increased, and the stress concentrated on the wrinkled, warped or curled portion of the flexible circuit module can be concentrated. Dispersion makes the flexible circuit module easy to flatten and attach, and can reduce the contact resistance between the conductive metal layer of the flexible circuit module and the conductor to which it is attached, and improve the conductive efficiency.
100‧‧‧可撓性電路模組 100‧‧‧Flexible circuit module
110‧‧‧可撓性電路模組 110‧‧‧Flexible circuit module
120‧‧‧可撓性電路模組 120‧‧‧Flexible circuit module
200‧‧‧可撓性基板 200‧‧‧Flexible substrate
210‧‧‧第一面 210‧‧‧ first side
220‧‧‧第二面 220‧‧‧ second side
300‧‧‧第一導電金屬層 300‧‧‧First conductive metal layer
300’‧‧‧導電金屬層 300'‧‧‧ Conductive metal layer
330‧‧‧穿孔部 330‧‧‧Perforated Department
340‧‧‧凸起部 340‧‧‧ raised parts
341‧‧‧環形凸起部 341‧‧‧Ring boss
400‧‧‧第一絕緣層 400‧‧‧First insulation
410‧‧‧裸露區域 410‧‧‧naked area
500‧‧‧第二導電金屬層 500‧‧‧Second conductive metal layer
600‧‧‧第二絕緣層 600‧‧‧Second insulation
700‧‧‧導電材料 700‧‧‧Electrical materials
900‧‧‧電子裝置 900‧‧‧Electronic devices
910‧‧‧預定位置 910‧‧‧Predetermined location
920‧‧‧導電膠 920‧‧‧Conductive adhesive
以下各圖中繪示的各元件的尺寸(長、寬、厚度等)僅為示意表示,各元件的實際尺寸可對應需要,適當地決定。 The dimensions (length, width, thickness, etc.) of the respective elements shown in the following figures are only schematic representations, and the actual dimensions of the respective elements may be appropriately determined depending on the needs.
圖1係本發明之可撓性電路模組一實施型態的俯視圖。 1 is a plan view showing an embodiment of a flexible circuit module of the present invention.
圖2係圖1中沿AA方向的斷面示意圖。 Figure 2 is a schematic cross-sectional view taken along line AA of Figure 1.
圖3係表示本發明之可撓性電路模組進行重工貼附的示意圖。 Fig. 3 is a schematic view showing the attachment of the flexible circuit module of the present invention to the rework.
圖4係本發明之可撓性電路模組另一實施型態的俯視圖。 4 is a plan view showing another embodiment of the flexible circuit module of the present invention.
圖5係圖4中沿BB方向的斷面示意圖。 Figure 5 is a schematic cross-sectional view taken along line BB of Figure 4.
圖6係本發明之可撓性電路模組另一實施型態的斷面示意圖。 Fig. 6 is a schematic cross-sectional view showing another embodiment of the flexible circuit module of the present invention.
圖7係表示習用之可撓性電路板進行重工貼附的示意圖。 Fig. 7 is a schematic view showing a conventional flexible circuit board attached to a rework.
100‧‧‧可撓性電路模組 100‧‧‧Flexible circuit module
200‧‧‧可撓性基板 200‧‧‧Flexible substrate
210‧‧‧第一面 210‧‧‧ first side
300‧‧‧第一導電金屬層 300‧‧‧First conductive metal layer
330‧‧‧穿孔部 330‧‧‧Perforated Department
340‧‧‧凸起部 340‧‧‧ raised parts
400‧‧‧第一絕緣層 400‧‧‧First insulation
410‧‧‧裸露區域 410‧‧‧naked area
900‧‧‧電子裝置 900‧‧‧Electronic devices
910‧‧‧預定位置 910‧‧‧Predetermined location
920‧‧‧導電膠 920‧‧‧Conductive adhesive
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CN115206190A (en) * | 2022-07-11 | 2022-10-18 | 武汉华星光电半导体显示技术有限公司 | Display device |
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CN105451458A (en) * | 2014-08-19 | 2016-03-30 | 宁波舜宇光电信息有限公司 | Method for controlling trace deformation of rigid-flex board and PCB substrate semi-finished product |
CN115206190A (en) * | 2022-07-11 | 2022-10-18 | 武汉华星光电半导体显示技术有限公司 | Display device |
CN115206190B (en) * | 2022-07-11 | 2023-11-28 | 武汉华星光电半导体显示技术有限公司 | display device |
Also Published As
Publication number | Publication date |
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CN102892251A (en) | 2013-01-23 |
TWI429352B (en) | 2014-03-01 |
CN102892251B (en) | 2015-05-20 |
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