TWI733585B - Optical lens, mold for optical lens and manufacturing method thereof - Google Patents
Optical lens, mold for optical lens and manufacturing method thereof Download PDFInfo
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Abstract
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本發明是有關於一種光學透鏡、光學透鏡成型模具及其製造方法。 The invention relates to an optical lens, an optical lens forming mold and a manufacturing method thereof.
光纖通訊具有傳輸效率佳、可抵抗電磁干擾及穩定性高等優點。光纖依傳輸方式可分為單模光纖及多模光纖,其中多模光纖的直徑遠大於光束之波長,因而允許不同波長和相位之光束沿光纖之周壁不停地反射傳輸,於長距離傳輸後會產生不同模式之間的傳播速度差,造成模態色散及光纖中心之光通量過高之問題,進而限制了傳輸距離。 Optical fiber communication has the advantages of good transmission efficiency, resistance to electromagnetic interference and high stability. Optical fiber can be divided into single-mode fiber and multi-mode fiber according to the transmission method. The diameter of the multi-mode fiber is much larger than the wavelength of the light beam, thus allowing light beams of different wavelengths and phases to be reflected and transmitted along the peripheral wall of the fiber. After long-distance transmission There will be a difference in propagation speed between different modes, resulting in modal dispersion and excessively high luminous flux in the center of the fiber, thereby limiting the transmission distance.
為解決前述之問題,一般會利用渦旋相位板使通過之光束轉換為渦旋光束,避免光強度集中於光纖之中央部分。然,渦旋相位板不易於製造,且習知之光通訊模組需要組裝多個光學元件以完成光路之布置,各該光學元件之設置位置些微的偏差都大幅影響光路之傳輸路徑,難以準確對位、加工不易且品質不一,進而導致傳輸效果不佳。 In order to solve the aforementioned problems, a vortex phase plate is generally used to convert the passing light beam into a vortex light beam to prevent the light intensity from being concentrated in the central part of the optical fiber. However, the vortex phase plate is not easy to manufacture, and the conventional optical communication module needs to assemble multiple optical elements to complete the arrangement of the optical path. The slight deviation of the installation position of each optical element greatly affects the transmission path of the optical path, and it is difficult to accurately The location, processing is not easy, and the quality is not uniform, which leads to poor transmission effect.
因此,有必要提供一種新穎且具有進步性之光學透鏡、光學透鏡成型模具及其製造方法,以解決上述之問題。 Therefore, it is necessary to provide a novel and progressive optical lens, an optical lens molding mold and a manufacturing method thereof to solve the above-mentioned problems.
本發明之主要目的在於提供一種光學透鏡、光學透鏡成型模具及其製造方法,其結構簡單、製程簡單、光束均勻分散、加工精密度佳且利於微小化。 The main purpose of the present invention is to provide an optical lens, an optical lens forming mold and a manufacturing method thereof, which has a simple structure, simple manufacturing process, uniform beam dispersion, good processing precision, and is conducive to miniaturization.
為達成上述目的,本發明提供一種光學透鏡,包括一繞一軸向螺旋之螺旋面及一被該螺旋面旋繞之中間結構,該中間結構相對於該螺旋面朝其中一側軸向延伸,該螺旋面繞行而形成一階差。 In order to achieve the above-mentioned object, the present invention provides an optical lens, which includes a spiral surface spiraling around an axial direction and an intermediate structure spiraled by the spiral surface. The intermediate structure extends axially toward one side of the spiral surface relative to the spiral surface. The spiral surface circulates to form a first step difference.
為達成上述目的,本發明另提供一種用於製造如上所述的光學透鏡之成型模具,包括一繞一軸向螺旋之螺旋面及一被該螺旋面旋繞之中間結構,該成型模具之中間結構相對於該成型模具之螺旋面朝其中一側軸向延伸,該成型模具之螺旋面繞行而形成一階差,該成型模具之螺旋面、中間結構及階差分別與該光學透鏡之螺旋面、中間結構及階差為相對互補。 In order to achieve the above object, the present invention further provides a molding die for manufacturing the optical lens as described above, which includes a spiral surface spiraling around an axial direction and an intermediate structure spiraled by the spiral surface. The intermediate structure of the molding mold With respect to the spiral surface of the forming mold extending axially toward one side, the spiral surface of the forming mold circulates to form a step difference. The spiral surface, intermediate structure and step difference of the forming mold are respectively the same as the spiral surface of the optical lens , Intermediate structure and step difference are relatively complementary.
為達成上述目的,本發明另提供一種用於製造如上所述的成型模具之製造方法,包括以下步驟:提供一基體,該基體包括一加工面;於該加工面加工形成該成型模具之螺旋面、中間結構及階差。 In order to achieve the above objective, the present invention further provides a manufacturing method for manufacturing the forming mold as described above, which includes the following steps: providing a base, the base including a processing surface; processing the spiral surface of the molding mold on the processing surface , Intermediate structure and level difference.
1:光學透鏡 1: Optical lens
2:成型模具 2: Forming mold
3:基體 3: matrix
4:刀具 4: Tool
11,21:軸向 11, 21: Axial
12,22:螺旋面 12, 22: spiral surface
13,23:中間結構 13,23: Intermediate structure
131,231:周壁 131, 231: Zhou Bi
14,24:階差 14,24: step difference
15,25:弧導面 15,25: arc guide surface
31:加工面 31: Machining surface
32:軸向 32: Axial
41,42:弧角 41, 42: arc angle
P1:參考平面 P1: Reference plane
P2:基準平面 P2: Datum plane
S:切削路徑 S: Cutting path
T1,T2,T3,T4:切線方向 T1, T2, T3, T4: Tangent direction
θ 1,θ 4:傾斜角
θ 2,θ 5:第一夾角
θ 3,θ 6:第二夾角
圖1為本發明一較佳實施例之成型模具之立體圖。 Fig. 1 is a perspective view of a forming mold according to a preferred embodiment of the present invention.
圖2為本發明一較佳實施例之成型模具之局部放大圖。 Fig. 2 is a partial enlarged view of a forming mold according to a preferred embodiment of the present invention.
圖3為本發明一較佳實施例之刀具之示意圖。 Fig. 3 is a schematic diagram of a cutting tool according to a preferred embodiment of the present invention.
圖4為本發明一較佳實施例之刀具之局部放大圖。 Fig. 4 is a partial enlarged view of a cutting tool according to a preferred embodiment of the present invention.
圖5為本發明一較佳實施例製造該成型模具之示意圖。 Fig. 5 is a schematic diagram of manufacturing the forming mold according to a preferred embodiment of the present invention.
圖6為本發明一較佳實施例之光學透鏡之示意圖。 Fig. 6 is a schematic diagram of an optical lens according to a preferred embodiment of the present invention.
圖7為本發明一較佳實施例之光學透鏡之局部放大圖。 Fig. 7 is a partial enlarged view of an optical lens according to a preferred embodiment of the present invention.
圖8為本發明一較佳實施例之光學透鏡所產生之光束均勻分散渦旋效果之示意圖。 FIG. 8 is a schematic diagram of the effect of uniformly dispersing the vortex of the light beam generated by the optical lens of a preferred embodiment of the present invention.
以下僅以實施例說明本發明可能之實施態樣,然並非用以限制本發明所欲保護之範疇,合先敘明。 The following examples are only used to illustrate the possible implementation aspects of the present invention, but they are not intended to limit the scope of protection of the present invention.
請參考圖1至5,其顯示本發明之一較佳實施例之用於製造如下所述的光學透鏡之成型模具2,其包括一繞一軸向21螺旋之螺旋面22及一被該螺旋面22旋繞之中間結構23,該成型模具2之中間結構23相對於該成型模具2之螺旋面22朝其中一側軸向延伸,該成型模具2之螺旋面22繞行而形成一階差24。
Please refer to Figures 1 to 5, which show a preferred embodiment of the present invention for manufacturing the optical
在本實施例中,該成型模具2之中間結構23為一凸柱,該凸柱之端面的直徑為大於等於0.001mm且小於等於0.02mm;該成型模具2之中間結構23與該成型模具2之螺旋面22之間具有一弧導面25,該成型模具2之弧導面25之弧半徑為大於等於0.001mm且小於等於0.02mm;該成型模具2之階差24為大於等於5μm且小於等於20μm;該成型模具2之中間結構23包括一周壁231,該成型模具2之周壁231相對於該成型模具2之軸向21成一大於等於1度且小於等於20度之傾斜角θ 4;定義一垂直於該成型模具2之軸向21之基準平面P2,該成型模具2之弧導面25之一外緣之切線方向T3與該基準平面P2界定一第一夾角θ 5,該成型模具2之螺旋面22之一外緣之切線方向T4與該基準平面P2界定一第二夾角θ 6,該成型模具
2之第一夾角θ 5大於該成型模具2之第二夾角θ 6,該成型模具2之第一夾角θ 5不小於17.0度,該成型模具2之第二夾角θ 6不小於0.70度,較佳地,該第一夾角θ 5約為17.2度,該第二夾角θ 6約為0.72度。
In this embodiment, the
請參考圖6至7,其顯示本發明之一較佳實施例之光學透鏡1,其包括一繞一軸向11螺旋之螺旋面12及一被該螺旋面12旋繞之中間結構13,該中間結構13相對於該螺旋面12朝其中一側軸向延伸,該螺旋面12繞行而形成一階差14。其中,該成型模具2之螺旋面22、中間結構23及階差24分別與該光學透鏡1之螺旋面12、中間結構13及階差14為相對互補。
Please refer to FIGS. 6-7, which show an
在本實施例中,該中間結構13為一凹孔(盲孔或穿孔),該凹孔之孔底緣的直徑為大於等於0.001mm且小於等於0.02mm;該中間結構13與該螺旋面12之間具有一弧導面15,該弧導面15之弧半徑為大於等於0.001mm且小於等於0.02mm;該階差14為大於等於5微米(μm)且小於等於20μm;該中間結構13包括一周壁131,該周壁131相對於該光學透鏡1之軸向11成一傾斜角θ 1,該周壁131軸向地超出該階差14,該傾斜角θ 1為大於等於1度且小於等於20度;定義一垂直於該光學透鏡1之軸向11之參考平面P1,該弧導面15之一外緣之切線方向T1與該參考平面P1界定一第一夾角θ 2,該螺旋面12之一外緣之切線方向T2與該參考平面P1界定一第二夾角θ 3,該第一夾角θ 2大於該第二夾角θ 3,該第一夾角θ 2不小於17.0度,該第二夾角θ 3不小於0.70度,較佳地,該第一夾角θ 2約為17.2度,該第二夾角θ 3約為0.72度。
In this embodiment, the
該光學透鏡1與該成型模具2在結構上為互補。例如,該光學透鏡1之中間結構13為一凹孔,該成型模具2之中間結構23為一凸柱,可理解的是,該光學透鏡1之中間結構13若為一凸柱,則該成型模具2之中間結構23為一凹孔。
The
請再參考圖1至5,本發明另提供一種用於製造如上所述的成型模具2之製造方法,包括以下步驟:提供一基體3,該基體3包括一加工面31;於該加工面31加工形成該成型模具2之螺旋面22、中間結構23及階差24。依據不同需求,可於該基體3上形成複數成型模穴,可供一次製造多個光學透鏡。較佳地,任相鄰二該成型模穴之間的一間隙為小於等於0.01mm,藉此,所製得之各光學透鏡之渦旋光束不相干涉。
Please refer to FIGS. 1 to 5 again. The present invention also provides a manufacturing method for manufacturing the forming
在本實施例中,係以一刀具4切削該加工面31而形成該成型模具2之螺旋面22、中間結構23及階差24,該刀具4於該基體3上相對之切削路徑S為螺旋地繞該基體3之一軸向32。切削時,該刀具4可為固定而旋轉該基體3,或該基體3可為固定而旋轉該刀具4,或該刀具4及該基體3同時配合轉動亦可,只要可沿預設切削路徑S切削該加工面31即可。詳細說,該刀具4之各切削路徑S為自該基體3之一相對高位由淺而深地旋繞該基體3之軸向,再自該基體3之一相對低位延伸回該基體3之相對高位。該刀具4係由外而內(亦可由內而外)螺旋地繞該基體3之軸向切削該加工面31。其中,係選用刀刃相對二側具有相異弧角41,42之刀具4,且以該刀具4之刀刃具有相對較小弧角41之一側朝內的配置方式切削該加工面31。較佳地,所選用之該刀具4之刀刃二側的弧角41,42分別具有小於等於1μm之弧角半徑及大於1μm且小於等於5μm之弧角半徑。
In this embodiment, a
另外說明的是,上述各結構之尺度條件,有利於該光束均勻分散渦旋,另允許在最佳精密度條件下加工(例如使用鑽石刀具)用於成型該光學透鏡之模具,使該模具易於被加工製造、拔模順暢(因該傾斜角)。在以鑽石刀具加工該用於成型該光學透鏡之模具的一實施例中,考量到加工至靠近模具中心時會有加工極限,該鑽石刀具靠近該模具中心之一側被建構成具有較其相 對側還小之刀刃弧角半徑,能將加工產生之自然弧角半徑降低至1μm以下,有利加工精密度及產品微小化。該模具之凹孔例如係以雷射加工而成,然亦可以其他加工方式製成。 In addition, it should be noted that the scale conditions of the above structures are conducive to the uniform dispersion of the vortex of the beam, and also allow processing under the best precision conditions (for example, the use of diamond tools) for molding the optical lens mold, making the mold easy It is processed and manufactured smoothly (due to the inclination angle). In an embodiment of processing the mold for molding the optical lens with a diamond tool, considering that there is a processing limit when processing close to the center of the mold, the side of the diamond tool near the center of the mold is constructed to have a higher The small arc angle radius of the cutting edge on the opposite side can reduce the natural arc angle radius produced by machining to less than 1μm, which is beneficial to machining precision and product miniaturization. The cavity of the mold is formed by laser processing, for example, but it can also be formed by other processing methods.
請參考圖8,其顯示本發明之光學透鏡所產生之光束均勻分散渦旋效果。圖8清楚顯示出,由於該光學透鏡之螺旋面的作用,光線被螺旋地均勻分散,且由於該光學透鏡之中間結構(例如凹孔或凸柱)的作用,光線被均勻分散環繞於該中間結構之外圍,可避免光束過度集中於中央部分,有效解決模態色散及光纖中心之光通量過高而限制了傳輸距離之問題。其中,透過該渦旋透鏡之直徑、螺旋面之角度、中間結構之尺寸、階差之尺寸等條件之各種不同數值組合,可獲得不同之光學效果。 Please refer to FIG. 8, which shows the uniform vortex dispersion effect of the light beam generated by the optical lens of the present invention. Figure 8 clearly shows that due to the function of the spiral surface of the optical lens, the light is uniformly dispersed spirally, and due to the intermediate structure of the optical lens (such as concave holes or convex pillars), the light is evenly dispersed around the middle At the periphery of the structure, the beam can be prevented from being excessively concentrated in the central part, effectively solving the problem of modal dispersion and excessive luminous flux in the center of the fiber, which limits the transmission distance. Among them, different optical effects can be obtained through various numerical combinations of the diameter of the vortex lens, the angle of the spiral surface, the size of the intermediate structure, and the size of the step difference.
1:光學透鏡 1: Optical lens
11:軸向 11: Axial
12:螺旋面 12: Spiral
13:中間結構 13: Intermediate structure
131:周壁 131: Zhou wall
14:階差 14: step difference
15:弧導面 15: Arc guide surface
P1:參考平面 P1: Reference plane
T1,T2:切線方向 T1, T2: Tangent direction
θ 1:傾斜角 θ 1: Tilt angle
θ 2:第一夾角 θ 2: The first included angle
θ 3:第二夾角 θ 3: The second included angle
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