200827810 九、發明說明: 【發明所屬之技術領域】 本發明關於-種鏡頭組裝技術,尤其係關於 於鏡頭模組組裝之鏡頭組裝系統。 嗯適用 【先前技術】 隨著科技之不斷發展’攜帶式電子裝置如行動電, 應用日盈廣泛,同時也日漸趨向於輕巧、美觀及:, 其中照相功能係近年流行的行動電話之附加功能。, 行動電話之數位相機模組不僅要滿足輕薄短小之要:用於 還須具有較高的照相性能。而用於組裝鏡頭模組之=’其 機鏡頭組裝機係影響鏡頭模組生產效率之主要機a歎位相 =通過改善鏡頭組裝機將有利於提高鏡頭模組:::生 、通常的鏡頭組裝機為單站式組裝機,該 治具也為單站式組裝治具,即在第_ w用的 裝的光學元件喊完成後,轉換到第二站^將所要組 —站組裝好的光學元件組絲所要組裝的再ί第 站組裝完成後,再轉換到第三站之治具上 弟- 具也分散安裝在各對應的組裝卫作站上。、、、、各個治 上述鏡頭組裝機為進行各組裝工 組裝好的鮮元件組,光學元件組红作轉換已 因此會浪費工時,同時在每個工作;=短:: 貝來組裝,浪費人力’因而降低了鏡頭模組之組= 200827810 【發明内容】 有鑒於此,有必要提供一種能提高鏡頭模組組裝效率 之鏡頭組裝糸統。 一種鏡頭組裝系統,用於組裝鏡頭模組。該鏡頭組裝 系統包括一個基座、一個設置於該基座上的鏡頭組裝治 具、至少一個設置於該基座上且與所述鏡頭組裝治具間隔 設置之光學元件組裝治具以及與所述鏡頭組裝治具及光學 元件組裝治具相對應且設置於所述基座上的至少兩個推 桿。所述光學元件組裝治具利用相應的推桿將複數個分散 的光學元件組裝成一個光學元件組。所述鏡頭組裝治具利 用相應的推桿將組裝在一起的光學元件組置入鏡筒中。 一種鏡頭組裝系統,用於組裝鏡頭模組,包括一個基 座、至少一個設置在該基座上之鏡頭組裝治具、至少一個 與所述鏡頭組裝治具相對應且設置在所述基座上之推桿, 所述鏡頭組裝治具利用相應之推桿將光學元件組裝在一 起,並利用該推桿將組裝好的光學元件組置入鏡筒中。 該鏡頭組裝系統把複數個分散之工作站整合在一個 鏡頭組裝系統中之基座上,即把複數個具有相應組裝功能 的組裝治具整合在一個基座上,使得在組裝過程中不必把 已組裝在一起的元件在各個工作站之間運送、轉換,同時 所有組裝治具的組裝工作係同時進行的,且該鏡頭組裝系 統可由一個人來操作,因此該鏡頭組裝系統節約了組裝工 時,且節省了人力,從而提高了鏡頭模組之組裝效率。 8 200827810 ^【實施方式】 為了對本發明作更進一步的說明,舉一較佳實施例並 配合圖式詳細描述如下。 請參閱圖1及圖2,本發明實施例之鏡頭組裝系統, 用於組裝鏡頭模組20,該鏡頭組裝系統包括一個基座11、 一個設置於基座11上的第一光學元件組裝治具12及第二 光學元件組裝治具13、一個設置於該基座11上的鏡頭組 裝治具14以及與第一、第二光學元件組裝治具12、13及 所述鏡頭組裝治具14相對應且設置於所述基座11上的第 一、第二、第三推桿15、16、17。優選地,在所述第一、 第二光學元件組裝治具12、13及所述鏡頭組裝治具14與 基座11之間還分別設置有一彈性件18、19、10,用於緩 衝來自相對應的第一、第二、第三推桿15、16、17之衝力。 所述鏡頭模組20包括一個鏡筒21、一個光學元件組 22以及一個間隔環23。 該鏡筒21用來容置光學元件組22,其大小及形狀由 需要來設定。 在本實施例中該鏡頭模組20的光學元件組22為一鏡 片組22,所述鏡片組22包括第一、第二、第三以及第四 鏡片221、222、223、224,其形狀與大小根據需要而設定, 優選地,各個鏡片都可通過過盈配合而固定在一起。 所述間隔環23用於調整鏡片之間之距離進而調整鏡 頭模組之焦距。該間隔環23之形狀與大小根據需要而設 200827810 . 所述基座11固定於機台(圖未示;)上,該基座11包括 一個上基座111及一個下基座112,且上、下基座111、112 可以在機台之控制下移動,優選地,第一、第二、第三推 桿15、16、17設置於上基座111上,第一、第二光學元件 組裝治具12、13以及鏡頭組裝治具14設置於下基座112 上。 所述第一、第二光學元件組裝治具12、13用於將分 散的第一、第二、第三以及第四鏡片221、222、223、224 組裝為一個鏡片組22。鑒於所組裝的光學元件之所能承受 之壓力,本實施例中提供了兩個光學元件組裝治具12、13 來將各光學元件組裝在一起,以保證待組裝光學元件不在 組裝時被壓壞。可以理解的是,在保證所要組裝的光學元 件完好的情況下,所述鏡頭組裝系統可以只設置一個光學 元件祖裝治具,即通過一個光學元件組裝治具將所有分散 的第第二、第三、第四鏡片221、222、223、224以及 間隔瓖23組裝在一起。可以理解,可視鏡片數量之多少可 適當增減光學元件組裝治具之數量,如三個、四個或更多。 以第一光學元件組裝治具12為例來說明該光學元件 组裝治具12之、结構及組裝原理。該光學元件組裝治具12 包括/個筒體I21、一個與該筒體m共軸設置的套筒122 议z個套設於該套筒122之中的緩衝桿123。 所述筒體121之内徑等於第二鏡片222之最大直徑, β於容ί該第二鏡片222。該筒體121之軸向長度根據需 要而级定。 200827810 •戶斤述套筒122優選地與筒體⑵一體成形,當然可以 .以其他方式固定相連,比如螺紋連接或钻接。該套筒122 之軸向長度根據需要而設定。 該套筒122之内徑大於第一鏡片221之最大直徑,且 相對於所述筒體121之-端設有一通孔1221。該通孔 之直徑小於套筒122之内徑。 所述緩衝桿123貫穿於所述套筒122之通孔1221中, 該缓7桿123包括一個柱體1232及一個與該柱體1232相 連之β 1231。所述柱體1232優選地與該端部1231 —體 成形且該緩衝桿123之軸向長度小於套筒122之軸向長度。 該鳊邛1231套設於套筒122中,且該端部1231之徑 向直位大於套同122之通孔1221之直徑且小於套筒工22 之内徑,以保證該頂桿123不會從所述套筒122中滑出。 該柱體1232套設於套筒122之通孔1221中,且該柱 體1232之直徑小於套筒122之通孔1221之直徑。 所述推桿15優選地為一圓柱形,可以理解的是,還 可以係其他形狀,如方形、長方形或中空柱體。該推桿15 設置於朝向第一筒體121之一端且與該筒體121共軸間隔 設置於機台(圖未示)之上基座112上,並可在機台之控制 下’可沿該推桿15之轴向方向活動。 所述彈性件18可以為一彈簧,設置在該第一光學元 件組裝治具12與下基座m之間且套設在緩衝桿123上, 用於緩衝來自推桿15之瞬間衝力,以防止推桿15壓壞所 抵的光學元件。 11 200827810 該弹性件18之内徑大於所述緩衝桿123之柱體1231 之直徑且小於第二筒體122之外徑。在該彈性件18之硬度 選用上,應保證所述缓衝桿123在推桿15之衝力下不會頂 住在筒體121中所容置的朝向該推桿15之光學元件,如第 一鏡片221,以防止該緩衝桿123在推桿15之衝力下壓壞 該光學元件。 所述第二光學元件組裝治具13與上述的第一光學元 件組裝治具12結構與組裝原理相同,包括與鏡片222相配 合的兩個筒體131、134、一個與該筒體134共轴設置的套 筒132以及一個貝牙於該套筒132之中的緩衝桿133,同 時在該缓衝杯上及在筒體134與下基座112之間設有 一個彈性件19。 所述筒體131之直徑大於筒體134之直徑且與該筒體 134相連,所述筒體134與套筒132相連,優選地,筒體 131、134以及套筒132 —體成形,當然可以以其他方式固 定相連,比如螺紋連接或粒接。 所述鏡頭組裝治具14包括一個第一筒體141、一個與 該第一筒體141固定相銜接且共軸設置的第二筒體142以 及一個套設於該第二筒體142之中的頂桿143。 所述第一筒體141之内徨等於所述鏡頭模組2〇之鏡 筒21之外徑,用於容置該鏡筒21。該第一筒體141之軸 向長度根據需要而設定。 所述第二筒體I42優選地與第一筒體141 一體成形, 當然玎以以其他方式固定相連,比如螺紋連接或粘接,只 12 200827810 要保證在作業時第一筒體141與第二筒體142不會相對運 動。該第二筒體142的軸向長度根據需要而設定。 該第二筒體142相對於所述第一筒體141之一端設有 一通孔1421,該通孔1421之直徑小於第二筒體142之内 徑。 該第二筒體142之内徑與鏡頭模組20之鏡片組22中 外徑最大之鏡片外徑相等,以保證組裝好的光學元件不易 活動。該第二筒體142之内徑小於第一筒體141之内徑, 以與第一筒體141配合形成平台1422,該平台1422用於 放置未組裝鏡片組22之鏡筒21。 該平台1422之徑向厚度由所述第一筒體141與第二 筒體142之内徑差決定。 所述頂桿143貫穿於所述第二筒體142之通孔1421 中。該頂桿143之形狀與如上所述的緩衝桿123 —樣,即 包括一個端部1431及一個柱體1432,其設置情況也與該 緩衝桿123之設置情況一樣,即保證該頂桿不從所述第二 筒體142中滑出。 該頂桿143還具有另外一個作用就是用於將容置於第 二筒體142中的鏡片組22從第二筒體142之相對於通孔 1421之開口中頂出,以把組裝在一起的鏡片組22置入放 置在第一筒體141之鏡筒21中。 所述推桿17與上述推桿15、16之作用及設置位置基 本相同,在此不作累述。 所述彈性件10之形狀與上述彈性件18相同,在此也 13 200827810200827810 IX. DESCRIPTION OF THE INVENTION: TECHNICAL FIELD OF THE INVENTION The present invention relates to a lens assembly technique, and more particularly to a lens assembly system for lens module assembly.嗯Applicable [Prior Art] With the continuous development of technology, portable electronic devices such as mobile phones have a wide range of applications, and they are becoming more and more lightweight and beautiful. The camera function is an additional feature of mobile phones that have been popular in recent years. The digital camera module of the mobile phone not only needs to meet the requirements of being light and thin: it must also have high photographic performance. And for the assembly of the lens module = 'the machine lens assembly machine affects the production efficiency of the lens module's main machine a sigh phase = by improving the lens assembly machine will help improve the lens module::: raw, normal lens assembly The machine is a single-station assembly machine, and the fixture is also a single-station assembly fixture, that is, after the optical component of the _w is completed, the switch is switched to the second station, and the assembled optical station is assembled. After assembly of the component wires, the assembly of the station is completed, and then the switch to the third station is also installed on the corresponding assembly station. The above-mentioned lens assembly machine is a group of fresh components assembled by each assembler. The red component conversion of the optical component group has been wasted work time and at the same time in each work; = short:: belle assembly, waste Manpower' thus reduces the group of lens modules = 200827810 [Invention] In view of this, it is necessary to provide a lens assembly system that can improve the assembly efficiency of the lens module. A lens assembly system for assembling a lens module. The lens assembly system includes a base, a lens assembly jig disposed on the base, at least one optical component assembly jig disposed on the base and spaced apart from the lens assembly fixture, and The lens assembly jig and the optical component assembly jig correspond to at least two push rods disposed on the base. The optical component assembly jig assembles a plurality of discrete optical components into an optical component group using respective push rods. The lens assembly jig uses the corresponding push rods to place the assembled optical component groups into the lens barrel. A lens assembly system for assembling a lens module, comprising a base, at least one lens assembly jig disposed on the base, at least one corresponding to the lens assembly fixture and disposed on the base The push rod, the lens assembly jig uses the corresponding push rod to assemble the optical components together, and uses the push rod to place the assembled optical component group into the lens barrel. The lens assembly system integrates a plurality of discrete workstations on a base in a lens assembly system, that is, a plurality of assembly fixtures having corresponding assembly functions are integrated on a base, so that it is not necessary to assemble in the assembly process. The components are transferred and converted between the workstations, and the assembly work of all the assembly fixtures is performed simultaneously, and the lens assembly system can be operated by one person, so the lens assembly system saves assembly man-hours and saves Manpower, which improves the assembly efficiency of the lens module. 8 200827810 [Embodiment] In order to further clarify the present invention, a preferred embodiment will be described in detail below with reference to the drawings. Referring to FIG. 1 and FIG. 2 , a lens assembly system according to an embodiment of the present invention is used to assemble a lens module 20 . The lens assembly system includes a base 11 and a first optical component assembly fixture disposed on the base 11 . 12 and the second optical component assembly jig 13 , a lens assembly jig 14 disposed on the base 11 and corresponding to the first and second optical component assembly jigs 12 and 13 and the lens assembly jig 14 And first, second, and third push rods 15, 16, 17 disposed on the base 11. Preferably, an elastic member 18, 19, 10 is further disposed between the first and second optical component assembly jigs 12, 13 and the lens assembly jig 14 and the base 11 for buffering the phase. Corresponding impulses of the first, second, and third push rods 15, 16, 17. The lens module 20 includes a lens barrel 21, an optical element group 22, and a spacer ring 23. The lens barrel 21 is for accommodating the optical element group 22, and its size and shape are set as needed. In this embodiment, the optical component group 22 of the lens module 20 is a lens group 22, and the lens group 22 includes first, second, third, and fourth lenses 221, 222, 223, and 224, and the shape thereof is The size is set as desired, and preferably each lens can be secured together by an interference fit. The spacer ring 23 is used to adjust the distance between the lenses to adjust the focal length of the lens module. The shape and size of the spacer ring 23 are set to 200827810 as needed. The base 11 is fixed on a machine table (not shown), and the base 11 includes an upper base 111 and a lower base 112. The lower bases 111, 112 can be moved under the control of the machine. Preferably, the first, second, and third push rods 15, 16, 17 are disposed on the upper base 111, and the first and second optical components are assembled. The jigs 12, 13 and the lens assembly jig 14 are disposed on the lower base 112. The first and second optical component assembly jigs 12, 13 are used to assemble the dispersed first, second, third, and fourth lenses 221, 222, 223, 224 into a lens group 22. In view of the pressure that the assembled optical component can withstand, two optical component assembly jigs 12, 13 are provided in the present embodiment to assemble the optical components together to ensure that the optical components to be assembled are not crushed during assembly. . It can be understood that, in the case that the optical component to be assembled is in good condition, the lens assembly system can be provided with only one optical component ancestor fixture, that is, the assembly fixture of one optical component will disperse the second and the second. Third, the fourth lenses 221, 222, 223, 224 and the spacers 23 are assembled. It will be appreciated that the number of visible lenses may suitably increase or decrease the number of optical component assembly fixtures, such as three, four or more. The structure, assembly principle of the optical component assembly jig 12 will be described by taking the first optical component assembly jig 12 as an example. The optical component assembly jig 12 includes a cylinder I21 and a sleeve 122 disposed coaxially with the cylinder m. The buffer rods 123 are disposed in the sleeve 122. The inner diameter of the cylinder 121 is equal to the maximum diameter of the second lens 222, and the second lens 222 is accommodated. The axial length of the barrel 121 is graded as needed. 200827810 • The housing sleeve 122 is preferably integrally formed with the barrel (2), and of course may be fixedly connected in other ways, such as threaded or drilled. The axial length of the sleeve 122 is set as needed. The inner diameter of the sleeve 122 is larger than the maximum diameter of the first lens 221, and a through hole 1221 is formed at the end of the cylindrical body 121. The diameter of the through hole is smaller than the inner diameter of the sleeve 122. The buffer rod 123 is inserted into the through hole 1221 of the sleeve 122. The slow rod 123 includes a cylinder 1232 and a β 1231 connected to the cylinder 1232. The post 1232 is preferably formed integrally with the end 1231 and the axial length of the bumper 123 is less than the axial length of the sleeve 122. The shank 1231 is sleeved in the sleeve 122, and the radial position of the end portion 1231 is larger than the diameter of the through hole 1221 of the sleeve 122 and smaller than the inner diameter of the sleeve 22 to ensure that the ejector pin 123 does not Sliding out of the sleeve 122. The cylinder 1232 is sleeved in the through hole 1221 of the sleeve 122, and the diameter of the cylinder 1232 is smaller than the diameter of the through hole 1221 of the sleeve 122. The pusher 15 is preferably a cylindrical shape, it being understood that other shapes, such as square, rectangular or hollow cylinders, may also be used. The push rod 15 is disposed at one end of the first cylindrical body 121 and is disposed at a distance from the cylindrical body 121 on the base 112 above the machine table (not shown), and can be along the control of the machine The push rod 15 is moved in the axial direction. The elastic member 18 can be a spring disposed between the first optical component assembly jig 12 and the lower base m and sleeved on the buffer rod 123 for buffering the instantaneous impulse from the push rod 15 to prevent The push rod 15 crushes the optic element that is resisted. 11 200827810 The inner diameter of the elastic member 18 is larger than the diameter of the cylinder 1231 of the buffer rod 123 and smaller than the outer diameter of the second cylinder 122. In the selection of the hardness of the elastic member 18, it should be ensured that the buffer rod 123 does not bear against the optical component facing the push rod 15 in the cylinder 121 under the impulse of the push rod 15, such as the first The lens 221 prevents the buffer rod 123 from crushing the optical element under the force of the push rod 15. The second optical component assembly jig 13 has the same structure and assembly principle as the first optical component assembly jig 12 described above, and includes two cylinders 131, 134 that cooperate with the lens 222, and one coaxial with the cylinder 134. A sleeve 132 is disposed and a bumper bar 133 is formed in the sleeve 132, and an elastic member 19 is disposed on the buffer cup and between the barrel 134 and the lower base 112. The diameter of the cylinder 131 is larger than the diameter of the cylinder 134 and is connected to the cylinder 134. The cylinder 134 is connected to the sleeve 132. Preferably, the cylinders 131, 134 and the sleeve 132 are integrally formed. Fixedly connected in other ways, such as threaded or grained. The lens assembly jig 14 includes a first cylinder 141, a second cylinder 142 that is fixedly coupled to the first cylinder 141 and coaxially disposed, and a sleeve disposed in the second cylinder 142. Jack 143. The inner circumference of the first cylinder 141 is equal to the outer diameter of the lens barrel 21 of the lens module 2, for accommodating the lens barrel 21. The axial length of the first cylinder 141 is set as needed. The second cylinder I42 is preferably integrally formed with the first cylinder 141, and of course, is fixedly connected by other means, such as screwing or bonding, only 12 200827810 to ensure the first cylinder 141 and the second during operation The barrel 142 does not move relative to each other. The axial length of the second cylinder 142 is set as needed. The second cylinder 142 is provided with a through hole 1421 at one end of the first cylinder 141. The diameter of the through hole 1421 is smaller than the inner diameter of the second cylinder 142. The inner diameter of the second cylinder 142 is equal to the outer diameter of the lens having the largest outer diameter of the lens group 22 of the lens module 20 to ensure that the assembled optical components are not easily movable. The inner diameter of the second cylinder 142 is smaller than the inner diameter of the first cylinder 141 to cooperate with the first cylinder 141 to form a platform 1422 for placing the lens barrel 21 of the unassembled lens group 22. The radial thickness of the platform 1422 is determined by the difference in inner diameter between the first cylinder 141 and the second cylinder 142. The jack 143 penetrates through the through hole 1421 of the second cylinder 142. The shape of the jack 143 is the same as that of the bumper 123 as described above, that is, it includes an end portion 1431 and a cylinder 1432, and the setting is also the same as that of the buffer rod 123, that is, the jack is not guaranteed. The second cylinder 142 slides out. The jack 143 also has another function for ejecting the lens group 22 received in the second cylinder 142 from the opening of the second cylinder 142 with respect to the through hole 1421 to assemble the assembled The lens group 22 is placed in the lens barrel 21 placed in the first cylinder 141. The action and setting position of the push rod 17 and the push rods 15 and 16 are substantially the same, and will not be described here. The shape of the elastic member 10 is the same as that of the elastic member 18 described above, and is also here 13 200827810
不作累述,但該彈性件10哈螇输於田L 丁 iu除綾衝作用外,還具有另外—個Not to be described in detail, but the elastic member 10 is lost to the field L Ding iu in addition to the smashing effect, but also has another
作用,即在組裝時,推桿n M ^ 1U Μ干U把弟一同體141 第二 142推向下基座112,在把锫菇爐如9n从技 °〗股 汜鏡頭杈組20的鏡片組22頂入錄 甸21後’當所述推桿17不再施力a μ 丹她力、巧鏡同21,並朝遠離下 基座112的方向移動時,利用該彈性件㈣所述第 141及第二筒體142朝遠離下基座112的方向頂出 於下一次組裝。 ,請參閱圖3,以上述實施例為例’彻該鏡頭組袭系 統為鏡頭模組20組裝待組裝元件如鏡筒21、第一、第一 第三、第四鏡片221、222、223、224以及間隔環23「該 組裝方法包括下列步驟: ~ 步驟-:提供上述的鏡頭組裝系統,包括—個 11、-個第-光學元件組裝治具12、—個第二光學元^且 裝治具13、一個鏡頭組裝系統14、第一、筮———'' 第一、弟二推桿 i5m-個以及在所述第一、第二光學元件組裝治 具12、13及所述鏡頭組裝治具14與基座η u t下基座ι12 之間分別設置的一個彈性件18、19、ΐ〇 ; 步驟二:提供上述的鏡頭模組20中之待級穿一 括一個鏡筒21及待組裝的第一、第二、筮二件’包 乐二、弟四鏡片 221、222、223、224以及間隔環23。 门 步驟三:先在第一光學元件組裝治具12中組裝 第二鏡片221、222,即先把第二鏡片222 : 一、 ΖΖ谷置於筒體121 中,再將第一鏡片221放置於第二鏡片222上,抄& Zi 推桿15抵住第一鏡片221,並使該推桿i 然谈利用 朝罪近下基座 14 200827810 112之方向移動,以將與該第二鏡片222相配合的第一鏡 片221與第二鏡片222組裝在一起。 步驟四:將在第一光學元件組裝治具12中組裝在一 起的第一、第二鏡片221、222容置在第二光學元件組裝治 具13之筒體134中,然後將第三鏡片223放置在第二鏡片 222上,最後利用推桿16將與第二鏡片222相配合的第三 鏡片223與第二鏡片222組裝在一起。與此同時,為第一 光學元件組裝治具放置要組裝的另外一個鏡頭模組的第 一、二鏡片。 步驟五:在第二光學元件組裝治具13中組裝間隔環 23以及第四鏡片224,即先將間隔環23及第四鏡片224 放置於第三鏡片223上,然後再利用推桿16將與第三鏡片 223相配合的間隔環23及第四鏡片224及該第三鏡片223 組裝在一起,此時,一個鏡片組22便組裝完成。與此同時, 重覆步驟三,即利用推桿15將與另外一個鏡頭模組的第二 鏡片相配合的第一鏡片與該第二鏡片組裝在一起。 步驟六:將組裝在一起的鏡片組22置入鏡頭組裝治 具14的第二筒體142中,並將鏡筒21置入第一筒體141 中,最後利用推桿17抵住第一筒體141中之鏡筒21,並 使該推桿17朝靠近下基座11方向移動直到所述鏡片組22 全部置入鏡筒21為止。與此同時,重覆步驟二至五,即完 成另外的鏡片組之組裝,以便進行後續組裝工序。 如此在鏡頭組裝治具14上完成對整個鏡頭模組20的 組裝,與此同時,在第二光學元件組裝治具13上將第二個 15 200827810 .鏡頭模組之鏡片組組裝在-起’在第—光學元件組裳治見 ,12上將第三個鏡頭模組的第一、第二鏡片組裝在—起。/、 上述鏡頭組裝治具14係採用倒裝方法將鏡片纟且2 壯 入鏡筒中’可以理解的是’該鏡頭組裝治具14 ^ 採用順裝方法組裝鏡頭模組20,即先在第一、第二光風 件組裝治具12、13中把各個鏡片組裝為一個鏡二2予广 同時將鏡筒21放置入鏡頭組裝治具u之第一筒體μ 中,然後把組裝好的鏡片組22利用推桿17將該鏡片組^ 壓入鏡筒21中,從而完成該鏡頭模組2〇之組裝。 另外’可以理解的是’也可以首先在鏡頭組装治星“ 中放置鏡筒21,然後再依序將第_、第二、第三、第^於 片221、222、223、224以及間隔環23等光學元件一一= 入鏡筒21中,從而完成鏡頭模組2〇之組裝 在上述整個鏡頭模組之組裝過程中’每一次組裝作業 所需要之工時由所述整個工作站中組裝工時最長之:站所 確定。 該鏡社裝线由於整㈣業過程巾,組裝光學元 件、將組裝好的光料件置人鏡筒中係同時進行的 ,且物 料沒有在工作台外暫留,也没有人工之運送造成的工時損 失1此在節省人工的同時,節約了工時,從而提高了鏡 頭模組之組裝生產率。 “上所述,本發明符合發明糊要件,爰依法提出專 二准以上所述者僅為本發明之較佳實施例,本發 明之粑圍並不以上述實施例為限,舉凡熟習本案技藝之人 16 200827810 士援依本發明之精神所作之等效修飾或變化,皆應涵蓋於 以下申請專利範圍内。 【圖式簡單說明】 圖1係本發明實施例之鏡頭組裝系統之結構示意圖; 圖2係本發明實施例中待組裝的鏡頭模組之結構示意 圖; 〜 圖3係圖1所示的鏡頭組裝系統處於一鏡頭模组袓 狀態示意圖。 、、、、、衣 【主要元件符號說明】 基座 11 下基座 112 第二光學元 件組裝治具 13 套筒 122、132 柱體 1231 、 1432 通孔 1221 、 1421 第一筒體 141 頂柱 143 彈性件 18 、 19 、 10 鏡頭模組 20 鏡片組 22 間隔環 23 上基座 111 第一光學元 件組裝治具 12 筒體 121 、 131 、 緩衝柱 134 123 、 133 端部 1232、1431 鏡頭組裳治具 14 第二筒體 142 平台 1422 推桿 15、16、17 鏡筒 21 第一、第二、 第 221、222、 二、弟四鏡片 223 、 224 17The role, that is, in the assembly, the push rod n M ^ 1U Μ 干 U 把 一 141 142 second 142 push down the pedestal 112, in the lens of the mushroom 如 如 如 20 After the group 22 enters the record 21, when the pusher 17 no longer applies a force, the force is the same as 21, and moves away from the lower base 112, the elastic member (4) is used. The 141 and the second cylinder 142 are mounted in the direction away from the lower base 112 for the next assembly. Please refer to FIG. 3 , taking the above embodiment as an example. The lens assembly system assembles components to be assembled such as the lens barrel 21 , the first, the third, the fourth and second lenses 221 , 222 , 223 . 224 and spacer ring 23 "The assembly method includes the following steps: ~ Step -: providing the lens assembly system described above, including - 11, a first - optical component assembly jig 12, a second optical element ^ and treatment A lens assembly system 14, a first, a 筮--"' first, two second push rod i5m- and the first and second optical component assembly jigs 12, 13 and the lens assembly An elastic member 18, 19, ΐ〇 respectively disposed between the jig 14 and the base η ut lower base ι12; Step 2: providing the above-mentioned lens module 20 to be stepped through a lens barrel 21 and to be assembled The first, second, and second pieces of 'Bule II, the fourth four lenses 221, 222, 223, 224 and the spacer ring 23. Step 3: First assembling the second lens 221 in the first optical component assembly jig 12 222, that is, first the second lens 222: a, the valley is placed in the cylinder 121, and then the first lens 221 Placed on the second lens 222, the copy & Zi push rod 15 is pressed against the first lens 221, and the push rod i is moved in the direction of the sin near the base 14 200827810 112 to be with the second The first lens 221 and the second lens 222 are matched with the lens 222. Step 4: The first and second lenses 221 and 222 assembled in the first optical component assembly jig 12 are placed in the second The optical component is assembled into the cylinder 134 of the jig 13, and then the third lens 223 is placed on the second lens 222, and finally the third lens 223 and the second lens 222 that cooperate with the second lens 222 are assembled by the push rod 16. At the same time, the first and second lenses of the other lens module to be assembled are placed for the first optical component assembly jig. Step 5: assembling the spacer ring 23 and the second optical component assembly jig 13 The four lenses 224, that is, the spacer ring 23 and the fourth lens 224 are first placed on the third lens 223, and then the spacer ring 23 and the fourth lens 224 and the third lens are matched with the third lens 223 by using the push rod 16. The lenses 223 are assembled together, at this time, a lens group 22 The assembly is completed. At the same time, step 3 is repeated, that is, the first lens matched with the second lens of the other lens module is assembled with the second lens by the push rod 15. Step 6: Will be assembled together The lens group 22 is placed in the second cylinder 142 of the lens assembly jig 14, and the lens barrel 21 is placed in the first cylinder 141, and finally the plunger 21 is pressed against the lens barrel 21 in the first cylinder 141 by the push rod 17. And the push rod 17 is moved toward the lower base 11 until the lens group 22 is entirely placed in the lens barrel 21. At the same time, steps two through five are repeated to complete the assembly of the additional lens sets for subsequent assembly steps. Thus, the assembly of the entire lens module 20 is completed on the lens assembly jig 14, and at the same time, the second lens assembly of the lens assembly of the first 15 200827810 lens module is assembled on the second optical component assembly jig 13 In the first optical component group, the first and second lenses of the third lens module are assembled. /, The above lens assembly jig 14 uses a flip-chip method to insert the lens into the lens barrel. 'Understandably, the lens assembly jig 14 ^ assembles the lens module 20 by the mounting method, that is, first in the first In the second light-winding assembly jigs 12 and 13, the lenses are assembled into a mirror 2 and the lens barrel 21 is placed in the first cylinder μ of the lens assembly j, and the assembled lens group is assembled. The lens assembly is pressed into the lens barrel 21 by the push rod 17, thereby completing the assembly of the lens module 2''. In addition, it can be understood that 'the lens barrel 21 can also be placed first in the lens assembly ruler, and then the _, second, third, and second sheets 221, 222, 223, 224 and the interval are sequentially arranged. The optical components such as the ring 23 are entered into the lens barrel 21 to complete the assembly of the lens module 2, and the assembly time of the entire lens module is assembled by the entire workstation during the assembly process required for each assembly operation. The longest working hours: the station is determined. The mirror assembly line is due to the whole (four) industry process towel, the assembly of the optical components, the assembly of the light components in the lens tube at the same time, and the materials are not left outside the workbench There is also no man-hour loss caused by manual transportation. This saves labor and saves man-hours, thereby improving the assembly productivity of the lens module. "The above description is in accordance with the invention. The above is only the preferred embodiment of the present invention, and the scope of the present invention is not limited to the above embodiments, and those skilled in the art will be equivalently modified according to the spirit of the present invention. Or change , It is intended to be included within the scope of the following claims. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic structural view of a lens assembly system according to an embodiment of the present invention; FIG. 2 is a schematic structural view of a lens module to be assembled in an embodiment of the present invention; FIG. 3 is a lens assembly shown in FIG. The system is in a state of a lens module. , , , , , [Main component symbol description] Base 11 Lower base 112 Second optical component assembly jig 13 Sleeve 122, 132 Cylinder 1231, 1432 Through hole 1221, 1421 First cylinder 141 Top post 143 Elastic member 18, 19, 10 Lens module 20 Lens group 22 Spacer ring 23 Upper base 111 First optical component assembly jig 12 Cylinders 121, 131, buffer column 134 123, 133 End 1232, 1431 Lens group 14 second cylinder 142 platform 1422 push rod 15, 16, 17 lens barrel 21 first, second, 221, 222, two, four four lenses 223, 224 17